| // Copyright 2016 the V8 project authors. All rights reserved. |
| // Use of this source code is governed by a BSD-style license that can be |
| // found in the LICENSE file. |
| |
| #include "src/code-stub-assembler.h" |
| |
| #include "src/code-factory.h" |
| #include "src/counters.h" |
| #include "src/frames-inl.h" |
| #include "src/frames.h" |
| #include "src/function-kind.h" |
| #include "src/heap/heap-inl.h" // For Page/MemoryChunk. TODO(jkummerow): Drop. |
| #include "src/objects/api-callbacks.h" |
| #include "src/objects/cell.h" |
| #include "src/objects/descriptor-array.h" |
| #include "src/objects/heap-number.h" |
| #include "src/objects/oddball.h" |
| #include "src/objects/ordered-hash-table-inl.h" |
| #include "src/objects/property-cell.h" |
| #include "src/wasm/wasm-objects.h" |
| |
| namespace v8 { |
| namespace internal { |
| |
| using compiler::Node; |
| template <class T> |
| using TNode = compiler::TNode<T>; |
| template <class T> |
| using SloppyTNode = compiler::SloppyTNode<T>; |
| |
| CodeStubAssembler::CodeStubAssembler(compiler::CodeAssemblerState* state) |
| : compiler::CodeAssembler(state), BaseBuiltinsFromDSLAssembler(state) { |
| if (DEBUG_BOOL && FLAG_csa_trap_on_node != nullptr) { |
| HandleBreakOnNode(); |
| } |
| } |
| |
| void CodeStubAssembler::HandleBreakOnNode() { |
| // FLAG_csa_trap_on_node should be in a form "STUB,NODE" where STUB is a |
| // string specifying the name of a stub and NODE is number specifying node id. |
| const char* name = state()->name(); |
| size_t name_length = strlen(name); |
| if (strncmp(FLAG_csa_trap_on_node, name, name_length) != 0) { |
| // Different name. |
| return; |
| } |
| size_t option_length = strlen(FLAG_csa_trap_on_node); |
| if (option_length < name_length + 2 || |
| FLAG_csa_trap_on_node[name_length] != ',') { |
| // Option is too short. |
| return; |
| } |
| const char* start = &FLAG_csa_trap_on_node[name_length + 1]; |
| char* end; |
| int node_id = static_cast<int>(strtol(start, &end, 10)); |
| if (start == end) { |
| // Bad node id. |
| return; |
| } |
| BreakOnNode(node_id); |
| } |
| |
| void CodeStubAssembler::Assert(const BranchGenerator& branch, |
| const char* message, const char* file, int line, |
| Node* extra_node1, const char* extra_node1_name, |
| Node* extra_node2, const char* extra_node2_name, |
| Node* extra_node3, const char* extra_node3_name, |
| Node* extra_node4, const char* extra_node4_name, |
| Node* extra_node5, |
| const char* extra_node5_name) { |
| #if defined(DEBUG) |
| if (FLAG_debug_code) { |
| Check(branch, message, file, line, extra_node1, extra_node1_name, |
| extra_node2, extra_node2_name, extra_node3, extra_node3_name, |
| extra_node4, extra_node4_name, extra_node5, extra_node5_name); |
| } |
| #endif |
| } |
| |
| void CodeStubAssembler::Assert(const NodeGenerator& condition_body, |
| const char* message, const char* file, int line, |
| Node* extra_node1, const char* extra_node1_name, |
| Node* extra_node2, const char* extra_node2_name, |
| Node* extra_node3, const char* extra_node3_name, |
| Node* extra_node4, const char* extra_node4_name, |
| Node* extra_node5, |
| const char* extra_node5_name) { |
| #if defined(DEBUG) |
| if (FLAG_debug_code) { |
| Check(condition_body, message, file, line, extra_node1, extra_node1_name, |
| extra_node2, extra_node2_name, extra_node3, extra_node3_name, |
| extra_node4, extra_node4_name, extra_node5, extra_node5_name); |
| } |
| #endif |
| } |
| |
| #ifdef DEBUG |
| namespace { |
| void MaybePrintNodeWithName(CodeStubAssembler* csa, Node* node, |
| const char* node_name) { |
| if (node != nullptr) { |
| csa->CallRuntime(Runtime::kPrintWithNameForAssert, csa->SmiConstant(0), |
| csa->StringConstant(node_name), node); |
| } |
| } |
| } // namespace |
| #endif |
| |
| void CodeStubAssembler::Check(const BranchGenerator& branch, |
| const char* message, const char* file, int line, |
| Node* extra_node1, const char* extra_node1_name, |
| Node* extra_node2, const char* extra_node2_name, |
| Node* extra_node3, const char* extra_node3_name, |
| Node* extra_node4, const char* extra_node4_name, |
| Node* extra_node5, const char* extra_node5_name) { |
| Label ok(this); |
| Label not_ok(this, Label::kDeferred); |
| if (message != nullptr && FLAG_code_comments) { |
| Comment("[ Assert: ", message); |
| } else { |
| Comment("[ Assert"); |
| } |
| branch(&ok, ¬_ok); |
| |
| BIND(¬_ok); |
| FailAssert(message, file, line, extra_node1, extra_node1_name, extra_node2, |
| extra_node2_name, extra_node3, extra_node3_name, extra_node4, |
| extra_node4_name, extra_node5, extra_node5_name); |
| |
| BIND(&ok); |
| Comment("] Assert"); |
| } |
| |
| void CodeStubAssembler::Check(const NodeGenerator& condition_body, |
| const char* message, const char* file, int line, |
| Node* extra_node1, const char* extra_node1_name, |
| Node* extra_node2, const char* extra_node2_name, |
| Node* extra_node3, const char* extra_node3_name, |
| Node* extra_node4, const char* extra_node4_name, |
| Node* extra_node5, const char* extra_node5_name) { |
| BranchGenerator branch = [=](Label* ok, Label* not_ok) { |
| Node* condition = condition_body(); |
| DCHECK_NOT_NULL(condition); |
| Branch(condition, ok, not_ok); |
| }; |
| |
| Check(branch, message, file, line, extra_node1, extra_node1_name, extra_node2, |
| extra_node2_name, extra_node3, extra_node3_name, extra_node4, |
| extra_node4_name, extra_node5, extra_node5_name); |
| } |
| |
| void CodeStubAssembler::FastCheck(TNode<BoolT> condition) { |
| Label ok(this), not_ok(this, Label::kDeferred); |
| Branch(condition, &ok, ¬_ok); |
| BIND(¬_ok); |
| { |
| DebugBreak(); |
| Goto(&ok); |
| } |
| BIND(&ok); |
| } |
| |
| void CodeStubAssembler::FailAssert( |
| const char* message, const char* file, int line, Node* extra_node1, |
| const char* extra_node1_name, Node* extra_node2, |
| const char* extra_node2_name, Node* extra_node3, |
| const char* extra_node3_name, Node* extra_node4, |
| const char* extra_node4_name, Node* extra_node5, |
| const char* extra_node5_name) { |
| DCHECK_NOT_NULL(message); |
| char chars[1024]; |
| Vector<char> buffer(chars); |
| if (file != nullptr) { |
| SNPrintF(buffer, "CSA_ASSERT failed: %s [%s:%d]\n", message, file, line); |
| } else { |
| SNPrintF(buffer, "CSA_ASSERT failed: %s\n", message); |
| } |
| Node* message_node = StringConstant(&(buffer[0])); |
| |
| #ifdef DEBUG |
| // Only print the extra nodes in debug builds. |
| MaybePrintNodeWithName(this, extra_node1, extra_node1_name); |
| MaybePrintNodeWithName(this, extra_node2, extra_node2_name); |
| MaybePrintNodeWithName(this, extra_node3, extra_node3_name); |
| MaybePrintNodeWithName(this, extra_node4, extra_node4_name); |
| MaybePrintNodeWithName(this, extra_node5, extra_node5_name); |
| #endif |
| |
| DebugAbort(message_node); |
| Unreachable(); |
| } |
| |
| Node* CodeStubAssembler::SelectImpl(TNode<BoolT> condition, |
| const NodeGenerator& true_body, |
| const NodeGenerator& false_body, |
| MachineRepresentation rep) { |
| VARIABLE(value, rep); |
| Label vtrue(this), vfalse(this), end(this); |
| Branch(condition, &vtrue, &vfalse); |
| |
| BIND(&vtrue); |
| { |
| value.Bind(true_body()); |
| Goto(&end); |
| } |
| BIND(&vfalse); |
| { |
| value.Bind(false_body()); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return value.value(); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::SelectInt32Constant( |
| SloppyTNode<BoolT> condition, int true_value, int false_value) { |
| return SelectConstant<Int32T>(condition, Int32Constant(true_value), |
| Int32Constant(false_value)); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::SelectIntPtrConstant( |
| SloppyTNode<BoolT> condition, int true_value, int false_value) { |
| return SelectConstant<IntPtrT>(condition, IntPtrConstant(true_value), |
| IntPtrConstant(false_value)); |
| } |
| |
| TNode<Oddball> CodeStubAssembler::SelectBooleanConstant( |
| SloppyTNode<BoolT> condition) { |
| return SelectConstant<Oddball>(condition, TrueConstant(), FalseConstant()); |
| } |
| |
| TNode<Smi> CodeStubAssembler::SelectSmiConstant(SloppyTNode<BoolT> condition, |
| Smi true_value, |
| Smi false_value) { |
| return SelectConstant<Smi>(condition, SmiConstant(true_value), |
| SmiConstant(false_value)); |
| } |
| |
| TNode<Object> CodeStubAssembler::NoContextConstant() { |
| return SmiConstant(Context::kNoContext); |
| } |
| |
| #define HEAP_CONSTANT_ACCESSOR(rootIndexName, rootAccessorName, name) \ |
| compiler::TNode<std::remove_pointer<std::remove_reference<decltype( \ |
| std::declval<Heap>().rootAccessorName())>::type>::type> \ |
| CodeStubAssembler::name##Constant() { \ |
| return UncheckedCast<std::remove_pointer<std::remove_reference<decltype( \ |
| std::declval<Heap>().rootAccessorName())>::type>::type>( \ |
| LoadRoot(RootIndex::k##rootIndexName)); \ |
| } |
| HEAP_MUTABLE_IMMOVABLE_OBJECT_LIST(HEAP_CONSTANT_ACCESSOR) |
| #undef HEAP_CONSTANT_ACCESSOR |
| |
| #define HEAP_CONSTANT_ACCESSOR(rootIndexName, rootAccessorName, name) \ |
| compiler::TNode<std::remove_pointer<std::remove_reference<decltype( \ |
| std::declval<ReadOnlyRoots>().rootAccessorName())>::type>::type> \ |
| CodeStubAssembler::name##Constant() { \ |
| return UncheckedCast<std::remove_pointer<std::remove_reference<decltype( \ |
| std::declval<ReadOnlyRoots>().rootAccessorName())>::type>::type>( \ |
| LoadRoot(RootIndex::k##rootIndexName)); \ |
| } |
| HEAP_IMMUTABLE_IMMOVABLE_OBJECT_LIST(HEAP_CONSTANT_ACCESSOR) |
| #undef HEAP_CONSTANT_ACCESSOR |
| |
| #define HEAP_CONSTANT_TEST(rootIndexName, rootAccessorName, name) \ |
| compiler::TNode<BoolT> CodeStubAssembler::Is##name( \ |
| SloppyTNode<Object> value) { \ |
| return WordEqual(value, name##Constant()); \ |
| } \ |
| compiler::TNode<BoolT> CodeStubAssembler::IsNot##name( \ |
| SloppyTNode<Object> value) { \ |
| return WordNotEqual(value, name##Constant()); \ |
| } |
| HEAP_IMMOVABLE_OBJECT_LIST(HEAP_CONSTANT_TEST) |
| #undef HEAP_CONSTANT_TEST |
| |
| Node* CodeStubAssembler::IntPtrOrSmiConstant(int value, ParameterMode mode) { |
| if (mode == SMI_PARAMETERS) { |
| return SmiConstant(value); |
| } else { |
| DCHECK_EQ(INTPTR_PARAMETERS, mode); |
| return IntPtrConstant(value); |
| } |
| } |
| |
| bool CodeStubAssembler::IsIntPtrOrSmiConstantZero(Node* test, |
| ParameterMode mode) { |
| int32_t constant_test; |
| Smi smi_test; |
| if (mode == INTPTR_PARAMETERS) { |
| if (ToInt32Constant(test, constant_test) && constant_test == 0) { |
| return true; |
| } |
| } else { |
| DCHECK_EQ(mode, SMI_PARAMETERS); |
| if (ToSmiConstant(test, &smi_test) && smi_test->value() == 0) { |
| return true; |
| } |
| } |
| return false; |
| } |
| |
| bool CodeStubAssembler::TryGetIntPtrOrSmiConstantValue(Node* maybe_constant, |
| int* value, |
| ParameterMode mode) { |
| int32_t int32_constant; |
| if (mode == INTPTR_PARAMETERS) { |
| if (ToInt32Constant(maybe_constant, int32_constant)) { |
| *value = int32_constant; |
| return true; |
| } |
| } else { |
| DCHECK_EQ(mode, SMI_PARAMETERS); |
| Smi smi_constant; |
| if (ToSmiConstant(maybe_constant, &smi_constant)) { |
| *value = Smi::ToInt(smi_constant); |
| return true; |
| } |
| } |
| return false; |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::IntPtrRoundUpToPowerOfTwo32( |
| TNode<IntPtrT> value) { |
| Comment("IntPtrRoundUpToPowerOfTwo32"); |
| CSA_ASSERT(this, UintPtrLessThanOrEqual(value, IntPtrConstant(0x80000000u))); |
| value = Signed(IntPtrSub(value, IntPtrConstant(1))); |
| for (int i = 1; i <= 16; i *= 2) { |
| value = Signed(WordOr(value, WordShr(value, IntPtrConstant(i)))); |
| } |
| return Signed(IntPtrAdd(value, IntPtrConstant(1))); |
| } |
| |
| Node* CodeStubAssembler::MatchesParameterMode(Node* value, ParameterMode mode) { |
| if (mode == SMI_PARAMETERS) { |
| return TaggedIsSmi(value); |
| } else { |
| return Int32Constant(1); |
| } |
| } |
| |
| TNode<BoolT> CodeStubAssembler::WordIsPowerOfTwo(SloppyTNode<IntPtrT> value) { |
| // value && !(value & (value - 1)) |
| return WordEqual( |
| Select<IntPtrT>( |
| WordEqual(value, IntPtrConstant(0)), |
| [=] { return IntPtrConstant(1); }, |
| [=] { return WordAnd(value, IntPtrSub(value, IntPtrConstant(1))); }), |
| IntPtrConstant(0)); |
| } |
| |
| TNode<Float64T> CodeStubAssembler::Float64Round(SloppyTNode<Float64T> x) { |
| Node* one = Float64Constant(1.0); |
| Node* one_half = Float64Constant(0.5); |
| |
| Label return_x(this); |
| |
| // Round up {x} towards Infinity. |
| VARIABLE(var_x, MachineRepresentation::kFloat64, Float64Ceil(x)); |
| |
| GotoIf(Float64LessThanOrEqual(Float64Sub(var_x.value(), one_half), x), |
| &return_x); |
| var_x.Bind(Float64Sub(var_x.value(), one)); |
| Goto(&return_x); |
| |
| BIND(&return_x); |
| return TNode<Float64T>::UncheckedCast(var_x.value()); |
| } |
| |
| TNode<Float64T> CodeStubAssembler::Float64Ceil(SloppyTNode<Float64T> x) { |
| if (IsFloat64RoundUpSupported()) { |
| return Float64RoundUp(x); |
| } |
| |
| Node* one = Float64Constant(1.0); |
| Node* zero = Float64Constant(0.0); |
| Node* two_52 = Float64Constant(4503599627370496.0E0); |
| Node* minus_two_52 = Float64Constant(-4503599627370496.0E0); |
| |
| VARIABLE(var_x, MachineRepresentation::kFloat64, x); |
| Label return_x(this), return_minus_x(this); |
| |
| // Check if {x} is greater than zero. |
| Label if_xgreaterthanzero(this), if_xnotgreaterthanzero(this); |
| Branch(Float64GreaterThan(x, zero), &if_xgreaterthanzero, |
| &if_xnotgreaterthanzero); |
| |
| BIND(&if_xgreaterthanzero); |
| { |
| // Just return {x} unless it's in the range ]0,2^52[. |
| GotoIf(Float64GreaterThanOrEqual(x, two_52), &return_x); |
| |
| // Round positive {x} towards Infinity. |
| var_x.Bind(Float64Sub(Float64Add(two_52, x), two_52)); |
| GotoIfNot(Float64LessThan(var_x.value(), x), &return_x); |
| var_x.Bind(Float64Add(var_x.value(), one)); |
| Goto(&return_x); |
| } |
| |
| BIND(&if_xnotgreaterthanzero); |
| { |
| // Just return {x} unless it's in the range ]-2^52,0[ |
| GotoIf(Float64LessThanOrEqual(x, minus_two_52), &return_x); |
| GotoIfNot(Float64LessThan(x, zero), &return_x); |
| |
| // Round negated {x} towards Infinity and return the result negated. |
| Node* minus_x = Float64Neg(x); |
| var_x.Bind(Float64Sub(Float64Add(two_52, minus_x), two_52)); |
| GotoIfNot(Float64GreaterThan(var_x.value(), minus_x), &return_minus_x); |
| var_x.Bind(Float64Sub(var_x.value(), one)); |
| Goto(&return_minus_x); |
| } |
| |
| BIND(&return_minus_x); |
| var_x.Bind(Float64Neg(var_x.value())); |
| Goto(&return_x); |
| |
| BIND(&return_x); |
| return TNode<Float64T>::UncheckedCast(var_x.value()); |
| } |
| |
| TNode<Float64T> CodeStubAssembler::Float64Floor(SloppyTNode<Float64T> x) { |
| if (IsFloat64RoundDownSupported()) { |
| return Float64RoundDown(x); |
| } |
| |
| Node* one = Float64Constant(1.0); |
| Node* zero = Float64Constant(0.0); |
| Node* two_52 = Float64Constant(4503599627370496.0E0); |
| Node* minus_two_52 = Float64Constant(-4503599627370496.0E0); |
| |
| VARIABLE(var_x, MachineRepresentation::kFloat64, x); |
| Label return_x(this), return_minus_x(this); |
| |
| // Check if {x} is greater than zero. |
| Label if_xgreaterthanzero(this), if_xnotgreaterthanzero(this); |
| Branch(Float64GreaterThan(x, zero), &if_xgreaterthanzero, |
| &if_xnotgreaterthanzero); |
| |
| BIND(&if_xgreaterthanzero); |
| { |
| // Just return {x} unless it's in the range ]0,2^52[. |
| GotoIf(Float64GreaterThanOrEqual(x, two_52), &return_x); |
| |
| // Round positive {x} towards -Infinity. |
| var_x.Bind(Float64Sub(Float64Add(two_52, x), two_52)); |
| GotoIfNot(Float64GreaterThan(var_x.value(), x), &return_x); |
| var_x.Bind(Float64Sub(var_x.value(), one)); |
| Goto(&return_x); |
| } |
| |
| BIND(&if_xnotgreaterthanzero); |
| { |
| // Just return {x} unless it's in the range ]-2^52,0[ |
| GotoIf(Float64LessThanOrEqual(x, minus_two_52), &return_x); |
| GotoIfNot(Float64LessThan(x, zero), &return_x); |
| |
| // Round negated {x} towards -Infinity and return the result negated. |
| Node* minus_x = Float64Neg(x); |
| var_x.Bind(Float64Sub(Float64Add(two_52, minus_x), two_52)); |
| GotoIfNot(Float64LessThan(var_x.value(), minus_x), &return_minus_x); |
| var_x.Bind(Float64Add(var_x.value(), one)); |
| Goto(&return_minus_x); |
| } |
| |
| BIND(&return_minus_x); |
| var_x.Bind(Float64Neg(var_x.value())); |
| Goto(&return_x); |
| |
| BIND(&return_x); |
| return TNode<Float64T>::UncheckedCast(var_x.value()); |
| } |
| |
| TNode<Float64T> CodeStubAssembler::Float64RoundToEven(SloppyTNode<Float64T> x) { |
| if (IsFloat64RoundTiesEvenSupported()) { |
| return Float64RoundTiesEven(x); |
| } |
| // See ES#sec-touint8clamp for details. |
| Node* f = Float64Floor(x); |
| Node* f_and_half = Float64Add(f, Float64Constant(0.5)); |
| |
| VARIABLE(var_result, MachineRepresentation::kFloat64); |
| Label return_f(this), return_f_plus_one(this), done(this); |
| |
| GotoIf(Float64LessThan(f_and_half, x), &return_f_plus_one); |
| GotoIf(Float64LessThan(x, f_and_half), &return_f); |
| { |
| Node* f_mod_2 = Float64Mod(f, Float64Constant(2.0)); |
| Branch(Float64Equal(f_mod_2, Float64Constant(0.0)), &return_f, |
| &return_f_plus_one); |
| } |
| |
| BIND(&return_f); |
| var_result.Bind(f); |
| Goto(&done); |
| |
| BIND(&return_f_plus_one); |
| var_result.Bind(Float64Add(f, Float64Constant(1.0))); |
| Goto(&done); |
| |
| BIND(&done); |
| return TNode<Float64T>::UncheckedCast(var_result.value()); |
| } |
| |
| TNode<Float64T> CodeStubAssembler::Float64Trunc(SloppyTNode<Float64T> x) { |
| if (IsFloat64RoundTruncateSupported()) { |
| return Float64RoundTruncate(x); |
| } |
| |
| Node* one = Float64Constant(1.0); |
| Node* zero = Float64Constant(0.0); |
| Node* two_52 = Float64Constant(4503599627370496.0E0); |
| Node* minus_two_52 = Float64Constant(-4503599627370496.0E0); |
| |
| VARIABLE(var_x, MachineRepresentation::kFloat64, x); |
| Label return_x(this), return_minus_x(this); |
| |
| // Check if {x} is greater than 0. |
| Label if_xgreaterthanzero(this), if_xnotgreaterthanzero(this); |
| Branch(Float64GreaterThan(x, zero), &if_xgreaterthanzero, |
| &if_xnotgreaterthanzero); |
| |
| BIND(&if_xgreaterthanzero); |
| { |
| if (IsFloat64RoundDownSupported()) { |
| var_x.Bind(Float64RoundDown(x)); |
| } else { |
| // Just return {x} unless it's in the range ]0,2^52[. |
| GotoIf(Float64GreaterThanOrEqual(x, two_52), &return_x); |
| |
| // Round positive {x} towards -Infinity. |
| var_x.Bind(Float64Sub(Float64Add(two_52, x), two_52)); |
| GotoIfNot(Float64GreaterThan(var_x.value(), x), &return_x); |
| var_x.Bind(Float64Sub(var_x.value(), one)); |
| } |
| Goto(&return_x); |
| } |
| |
| BIND(&if_xnotgreaterthanzero); |
| { |
| if (IsFloat64RoundUpSupported()) { |
| var_x.Bind(Float64RoundUp(x)); |
| Goto(&return_x); |
| } else { |
| // Just return {x} unless its in the range ]-2^52,0[. |
| GotoIf(Float64LessThanOrEqual(x, minus_two_52), &return_x); |
| GotoIfNot(Float64LessThan(x, zero), &return_x); |
| |
| // Round negated {x} towards -Infinity and return result negated. |
| Node* minus_x = Float64Neg(x); |
| var_x.Bind(Float64Sub(Float64Add(two_52, minus_x), two_52)); |
| GotoIfNot(Float64GreaterThan(var_x.value(), minus_x), &return_minus_x); |
| var_x.Bind(Float64Sub(var_x.value(), one)); |
| Goto(&return_minus_x); |
| } |
| } |
| |
| BIND(&return_minus_x); |
| var_x.Bind(Float64Neg(var_x.value())); |
| Goto(&return_x); |
| |
| BIND(&return_x); |
| return TNode<Float64T>::UncheckedCast(var_x.value()); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsValidSmi(TNode<Smi> smi) { |
| if (SmiValuesAre31Bits() && kSystemPointerSize == kInt64Size) { |
| // Check that the Smi value is properly sign-extended. |
| TNode<IntPtrT> value = Signed(BitcastTaggedToWord(smi)); |
| return WordEqual(value, ChangeInt32ToIntPtr(TruncateIntPtrToInt32(value))); |
| } |
| return Int32TrueConstant(); |
| } |
| |
| Node* CodeStubAssembler::SmiShiftBitsConstant() { |
| return IntPtrConstant(kSmiShiftSize + kSmiTagSize); |
| } |
| |
| TNode<Smi> CodeStubAssembler::SmiFromInt32(SloppyTNode<Int32T> value) { |
| TNode<IntPtrT> value_intptr = ChangeInt32ToIntPtr(value); |
| TNode<Smi> smi = |
| BitcastWordToTaggedSigned(WordShl(value_intptr, SmiShiftBitsConstant())); |
| return smi; |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsValidPositiveSmi(TNode<IntPtrT> value) { |
| intptr_t constant_value; |
| if (ToIntPtrConstant(value, constant_value)) { |
| return (static_cast<uintptr_t>(constant_value) <= |
| static_cast<uintptr_t>(Smi::kMaxValue)) |
| ? Int32TrueConstant() |
| : Int32FalseConstant(); |
| } |
| |
| return UintPtrLessThanOrEqual(value, IntPtrConstant(Smi::kMaxValue)); |
| } |
| |
| TNode<Smi> CodeStubAssembler::SmiTag(SloppyTNode<IntPtrT> value) { |
| int32_t constant_value; |
| if (ToInt32Constant(value, constant_value) && Smi::IsValid(constant_value)) { |
| return SmiConstant(constant_value); |
| } |
| TNode<Smi> smi = |
| BitcastWordToTaggedSigned(WordShl(value, SmiShiftBitsConstant())); |
| return smi; |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::SmiUntag(SloppyTNode<Smi> value) { |
| intptr_t constant_value; |
| if (ToIntPtrConstant(value, constant_value)) { |
| return IntPtrConstant(constant_value >> (kSmiShiftSize + kSmiTagSize)); |
| } |
| return Signed(WordSar(BitcastTaggedToWord(value), SmiShiftBitsConstant())); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::SmiToInt32(SloppyTNode<Smi> value) { |
| TNode<IntPtrT> result = SmiUntag(value); |
| return TruncateIntPtrToInt32(result); |
| } |
| |
| TNode<Float64T> CodeStubAssembler::SmiToFloat64(SloppyTNode<Smi> value) { |
| return ChangeInt32ToFloat64(SmiToInt32(value)); |
| } |
| |
| TNode<Smi> CodeStubAssembler::SmiMax(TNode<Smi> a, TNode<Smi> b) { |
| return SelectConstant<Smi>(SmiLessThan(a, b), b, a); |
| } |
| |
| TNode<Smi> CodeStubAssembler::SmiMin(TNode<Smi> a, TNode<Smi> b) { |
| return SelectConstant<Smi>(SmiLessThan(a, b), a, b); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::TryIntPtrAdd(TNode<IntPtrT> a, |
| TNode<IntPtrT> b, |
| Label* if_overflow) { |
| TNode<PairT<IntPtrT, BoolT>> pair = IntPtrAddWithOverflow(a, b); |
| TNode<BoolT> overflow = Projection<1>(pair); |
| GotoIf(overflow, if_overflow); |
| return Projection<0>(pair); |
| } |
| |
| TNode<Smi> CodeStubAssembler::TrySmiAdd(TNode<Smi> lhs, TNode<Smi> rhs, |
| Label* if_overflow) { |
| if (SmiValuesAre32Bits()) { |
| return BitcastWordToTaggedSigned(TryIntPtrAdd( |
| BitcastTaggedToWord(lhs), BitcastTaggedToWord(rhs), if_overflow)); |
| } else { |
| DCHECK(SmiValuesAre31Bits()); |
| TNode<PairT<Int32T, BoolT>> pair = |
| Int32AddWithOverflow(TruncateIntPtrToInt32(BitcastTaggedToWord(lhs)), |
| TruncateIntPtrToInt32(BitcastTaggedToWord(rhs))); |
| TNode<BoolT> overflow = Projection<1>(pair); |
| GotoIf(overflow, if_overflow); |
| TNode<Int32T> result = Projection<0>(pair); |
| return BitcastWordToTaggedSigned(ChangeInt32ToIntPtr(result)); |
| } |
| } |
| |
| TNode<Smi> CodeStubAssembler::TrySmiSub(TNode<Smi> lhs, TNode<Smi> rhs, |
| Label* if_overflow) { |
| if (SmiValuesAre32Bits()) { |
| TNode<PairT<IntPtrT, BoolT>> pair = IntPtrSubWithOverflow( |
| BitcastTaggedToWord(lhs), BitcastTaggedToWord(rhs)); |
| TNode<BoolT> overflow = Projection<1>(pair); |
| GotoIf(overflow, if_overflow); |
| TNode<IntPtrT> result = Projection<0>(pair); |
| return BitcastWordToTaggedSigned(result); |
| } else { |
| DCHECK(SmiValuesAre31Bits()); |
| TNode<PairT<Int32T, BoolT>> pair = |
| Int32SubWithOverflow(TruncateIntPtrToInt32(BitcastTaggedToWord(lhs)), |
| TruncateIntPtrToInt32(BitcastTaggedToWord(rhs))); |
| TNode<BoolT> overflow = Projection<1>(pair); |
| GotoIf(overflow, if_overflow); |
| TNode<Int32T> result = Projection<0>(pair); |
| return BitcastWordToTaggedSigned(ChangeInt32ToIntPtr(result)); |
| } |
| } |
| |
| TNode<Number> CodeStubAssembler::NumberMax(SloppyTNode<Number> a, |
| SloppyTNode<Number> b) { |
| // TODO(danno): This could be optimized by specifically handling smi cases. |
| TVARIABLE(Number, result); |
| Label done(this), greater_than_equal_a(this), greater_than_equal_b(this); |
| GotoIfNumberGreaterThanOrEqual(a, b, &greater_than_equal_a); |
| GotoIfNumberGreaterThanOrEqual(b, a, &greater_than_equal_b); |
| result = NanConstant(); |
| Goto(&done); |
| BIND(&greater_than_equal_a); |
| result = a; |
| Goto(&done); |
| BIND(&greater_than_equal_b); |
| result = b; |
| Goto(&done); |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::NumberMin(SloppyTNode<Number> a, |
| SloppyTNode<Number> b) { |
| // TODO(danno): This could be optimized by specifically handling smi cases. |
| TVARIABLE(Number, result); |
| Label done(this), greater_than_equal_a(this), greater_than_equal_b(this); |
| GotoIfNumberGreaterThanOrEqual(a, b, &greater_than_equal_a); |
| GotoIfNumberGreaterThanOrEqual(b, a, &greater_than_equal_b); |
| result = NanConstant(); |
| Goto(&done); |
| BIND(&greater_than_equal_a); |
| result = b; |
| Goto(&done); |
| BIND(&greater_than_equal_b); |
| result = a; |
| Goto(&done); |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::ConvertToRelativeIndex( |
| TNode<Context> context, TNode<Object> index, TNode<IntPtrT> length) { |
| TVARIABLE(IntPtrT, result); |
| |
| TNode<Number> const index_int = |
| ToInteger_Inline(context, index, CodeStubAssembler::kTruncateMinusZero); |
| TNode<IntPtrT> zero = IntPtrConstant(0); |
| |
| Label done(this); |
| Label if_issmi(this), if_isheapnumber(this, Label::kDeferred); |
| Branch(TaggedIsSmi(index_int), &if_issmi, &if_isheapnumber); |
| |
| BIND(&if_issmi); |
| { |
| TNode<Smi> const index_smi = CAST(index_int); |
| result = Select<IntPtrT>( |
| IntPtrLessThan(SmiUntag(index_smi), zero), |
| [=] { return IntPtrMax(IntPtrAdd(length, SmiUntag(index_smi)), zero); }, |
| [=] { return IntPtrMin(SmiUntag(index_smi), length); }); |
| Goto(&done); |
| } |
| |
| BIND(&if_isheapnumber); |
| { |
| // If {index} is a heap number, it is definitely out of bounds. If it is |
| // negative, {index} = max({length} + {index}),0) = 0'. If it is positive, |
| // set {index} to {length}. |
| TNode<HeapNumber> const index_hn = CAST(index_int); |
| TNode<Float64T> const float_zero = Float64Constant(0.); |
| TNode<Float64T> const index_float = LoadHeapNumberValue(index_hn); |
| result = SelectConstant<IntPtrT>(Float64LessThan(index_float, float_zero), |
| zero, length); |
| Goto(&done); |
| } |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::SmiMod(TNode<Smi> a, TNode<Smi> b) { |
| TVARIABLE(Number, var_result); |
| Label return_result(this, &var_result), |
| return_minuszero(this, Label::kDeferred), |
| return_nan(this, Label::kDeferred); |
| |
| // Untag {a} and {b}. |
| TNode<Int32T> int_a = SmiToInt32(a); |
| TNode<Int32T> int_b = SmiToInt32(b); |
| |
| // Return NaN if {b} is zero. |
| GotoIf(Word32Equal(int_b, Int32Constant(0)), &return_nan); |
| |
| // Check if {a} is non-negative. |
| Label if_aisnotnegative(this), if_aisnegative(this, Label::kDeferred); |
| Branch(Int32LessThanOrEqual(Int32Constant(0), int_a), &if_aisnotnegative, |
| &if_aisnegative); |
| |
| BIND(&if_aisnotnegative); |
| { |
| // Fast case, don't need to check any other edge cases. |
| TNode<Int32T> r = Int32Mod(int_a, int_b); |
| var_result = SmiFromInt32(r); |
| Goto(&return_result); |
| } |
| |
| BIND(&if_aisnegative); |
| { |
| if (SmiValuesAre32Bits()) { |
| // Check if {a} is kMinInt and {b} is -1 (only relevant if the |
| // kMinInt is actually representable as a Smi). |
| Label join(this); |
| GotoIfNot(Word32Equal(int_a, Int32Constant(kMinInt)), &join); |
| GotoIf(Word32Equal(int_b, Int32Constant(-1)), &return_minuszero); |
| Goto(&join); |
| BIND(&join); |
| } |
| |
| // Perform the integer modulus operation. |
| TNode<Int32T> r = Int32Mod(int_a, int_b); |
| |
| // Check if {r} is zero, and if so return -0, because we have to |
| // take the sign of the left hand side {a}, which is negative. |
| GotoIf(Word32Equal(r, Int32Constant(0)), &return_minuszero); |
| |
| // The remainder {r} can be outside the valid Smi range on 32bit |
| // architectures, so we cannot just say SmiFromInt32(r) here. |
| var_result = ChangeInt32ToTagged(r); |
| Goto(&return_result); |
| } |
| |
| BIND(&return_minuszero); |
| var_result = MinusZeroConstant(); |
| Goto(&return_result); |
| |
| BIND(&return_nan); |
| var_result = NanConstant(); |
| Goto(&return_result); |
| |
| BIND(&return_result); |
| return var_result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::SmiMul(TNode<Smi> a, TNode<Smi> b) { |
| TVARIABLE(Number, var_result); |
| VARIABLE(var_lhs_float64, MachineRepresentation::kFloat64); |
| VARIABLE(var_rhs_float64, MachineRepresentation::kFloat64); |
| Label return_result(this, &var_result); |
| |
| // Both {a} and {b} are Smis. Convert them to integers and multiply. |
| Node* lhs32 = SmiToInt32(a); |
| Node* rhs32 = SmiToInt32(b); |
| Node* pair = Int32MulWithOverflow(lhs32, rhs32); |
| |
| Node* overflow = Projection(1, pair); |
| |
| // Check if the multiplication overflowed. |
| Label if_overflow(this, Label::kDeferred), if_notoverflow(this); |
| Branch(overflow, &if_overflow, &if_notoverflow); |
| BIND(&if_notoverflow); |
| { |
| // If the answer is zero, we may need to return -0.0, depending on the |
| // input. |
| Label answer_zero(this), answer_not_zero(this); |
| Node* answer = Projection(0, pair); |
| Node* zero = Int32Constant(0); |
| Branch(Word32Equal(answer, zero), &answer_zero, &answer_not_zero); |
| BIND(&answer_not_zero); |
| { |
| var_result = ChangeInt32ToTagged(answer); |
| Goto(&return_result); |
| } |
| BIND(&answer_zero); |
| { |
| Node* or_result = Word32Or(lhs32, rhs32); |
| Label if_should_be_negative_zero(this), if_should_be_zero(this); |
| Branch(Int32LessThan(or_result, zero), &if_should_be_negative_zero, |
| &if_should_be_zero); |
| BIND(&if_should_be_negative_zero); |
| { |
| var_result = MinusZeroConstant(); |
| Goto(&return_result); |
| } |
| BIND(&if_should_be_zero); |
| { |
| var_result = SmiConstant(0); |
| Goto(&return_result); |
| } |
| } |
| } |
| BIND(&if_overflow); |
| { |
| var_lhs_float64.Bind(SmiToFloat64(a)); |
| var_rhs_float64.Bind(SmiToFloat64(b)); |
| Node* value = Float64Mul(var_lhs_float64.value(), var_rhs_float64.value()); |
| var_result = AllocateHeapNumberWithValue(value); |
| Goto(&return_result); |
| } |
| |
| BIND(&return_result); |
| return var_result.value(); |
| } |
| |
| TNode<Smi> CodeStubAssembler::TrySmiDiv(TNode<Smi> dividend, TNode<Smi> divisor, |
| Label* bailout) { |
| // Both {a} and {b} are Smis. Bailout to floating point division if {divisor} |
| // is zero. |
| GotoIf(WordEqual(divisor, SmiConstant(0)), bailout); |
| |
| // Do floating point division if {dividend} is zero and {divisor} is |
| // negative. |
| Label dividend_is_zero(this), dividend_is_not_zero(this); |
| Branch(WordEqual(dividend, SmiConstant(0)), ÷nd_is_zero, |
| ÷nd_is_not_zero); |
| |
| BIND(÷nd_is_zero); |
| { |
| GotoIf(SmiLessThan(divisor, SmiConstant(0)), bailout); |
| Goto(÷nd_is_not_zero); |
| } |
| BIND(÷nd_is_not_zero); |
| |
| TNode<Int32T> untagged_divisor = SmiToInt32(divisor); |
| TNode<Int32T> untagged_dividend = SmiToInt32(dividend); |
| |
| // Do floating point division if {dividend} is kMinInt (or kMinInt - 1 |
| // if the Smi size is 31) and {divisor} is -1. |
| Label divisor_is_minus_one(this), divisor_is_not_minus_one(this); |
| Branch(Word32Equal(untagged_divisor, Int32Constant(-1)), |
| &divisor_is_minus_one, &divisor_is_not_minus_one); |
| |
| BIND(&divisor_is_minus_one); |
| { |
| GotoIf(Word32Equal( |
| untagged_dividend, |
| Int32Constant(kSmiValueSize == 32 ? kMinInt : (kMinInt >> 1))), |
| bailout); |
| Goto(&divisor_is_not_minus_one); |
| } |
| BIND(&divisor_is_not_minus_one); |
| |
| TNode<Int32T> untagged_result = Int32Div(untagged_dividend, untagged_divisor); |
| TNode<Int32T> truncated = Signed(Int32Mul(untagged_result, untagged_divisor)); |
| |
| // Do floating point division if the remainder is not 0. |
| GotoIf(Word32NotEqual(untagged_dividend, truncated), bailout); |
| |
| return SmiFromInt32(untagged_result); |
| } |
| |
| TNode<Smi> CodeStubAssembler::SmiLexicographicCompare(TNode<Smi> x, |
| TNode<Smi> y) { |
| TNode<ExternalReference> smi_lexicographic_compare = |
| ExternalConstant(ExternalReference::smi_lexicographic_compare_function()); |
| TNode<ExternalReference> isolate_ptr = |
| ExternalConstant(ExternalReference::isolate_address(isolate())); |
| return CAST(CallCFunction3(MachineType::AnyTagged(), MachineType::Pointer(), |
| MachineType::AnyTagged(), MachineType::AnyTagged(), |
| smi_lexicographic_compare, isolate_ptr, x, y)); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::TruncateIntPtrToInt32( |
| SloppyTNode<IntPtrT> value) { |
| if (Is64()) { |
| return TruncateInt64ToInt32(ReinterpretCast<Int64T>(value)); |
| } |
| return ReinterpretCast<Int32T>(value); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::TaggedIsSmi(SloppyTNode<Object> a) { |
| return WordEqual(WordAnd(BitcastTaggedToWord(a), IntPtrConstant(kSmiTagMask)), |
| IntPtrConstant(0)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::TaggedIsSmi(TNode<MaybeObject> a) { |
| return WordEqual( |
| WordAnd(BitcastMaybeObjectToWord(a), IntPtrConstant(kSmiTagMask)), |
| IntPtrConstant(0)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::TaggedIsNotSmi(SloppyTNode<Object> a) { |
| return WordNotEqual( |
| WordAnd(BitcastTaggedToWord(a), IntPtrConstant(kSmiTagMask)), |
| IntPtrConstant(0)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::TaggedIsPositiveSmi(SloppyTNode<Object> a) { |
| return WordEqual(WordAnd(BitcastTaggedToWord(a), |
| IntPtrConstant(kSmiTagMask | kSmiSignMask)), |
| IntPtrConstant(0)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::WordIsAligned(SloppyTNode<WordT> word, |
| size_t alignment) { |
| DCHECK(base::bits::IsPowerOfTwo(alignment)); |
| return WordEqual(IntPtrConstant(0), |
| WordAnd(word, IntPtrConstant(alignment - 1))); |
| } |
| |
| #if DEBUG |
| void CodeStubAssembler::Bind(Label* label, AssemblerDebugInfo debug_info) { |
| CodeAssembler::Bind(label, debug_info); |
| } |
| #endif // DEBUG |
| |
| void CodeStubAssembler::Bind(Label* label) { CodeAssembler::Bind(label); } |
| |
| TNode<Float64T> CodeStubAssembler::LoadDoubleWithHoleCheck( |
| TNode<FixedDoubleArray> array, TNode<Smi> index, Label* if_hole) { |
| return LoadFixedDoubleArrayElement(array, index, MachineType::Float64(), 0, |
| SMI_PARAMETERS, if_hole); |
| } |
| |
| TNode<Float64T> CodeStubAssembler::LoadDoubleWithHoleCheck( |
| TNode<FixedDoubleArray> array, TNode<IntPtrT> index, Label* if_hole) { |
| return LoadFixedDoubleArrayElement(array, index, MachineType::Float64(), 0, |
| INTPTR_PARAMETERS, if_hole); |
| } |
| |
| void CodeStubAssembler::BranchIfPrototypesHaveNoElements( |
| Node* receiver_map, Label* definitely_no_elements, |
| Label* possibly_elements) { |
| CSA_SLOW_ASSERT(this, IsMap(receiver_map)); |
| VARIABLE(var_map, MachineRepresentation::kTagged, receiver_map); |
| Label loop_body(this, &var_map); |
| Node* empty_fixed_array = LoadRoot(RootIndex::kEmptyFixedArray); |
| Node* empty_slow_element_dictionary = |
| LoadRoot(RootIndex::kEmptySlowElementDictionary); |
| Goto(&loop_body); |
| |
| BIND(&loop_body); |
| { |
| Node* map = var_map.value(); |
| Node* prototype = LoadMapPrototype(map); |
| GotoIf(IsNull(prototype), definitely_no_elements); |
| Node* prototype_map = LoadMap(prototype); |
| TNode<Int32T> prototype_instance_type = LoadMapInstanceType(prototype_map); |
| |
| // Pessimistically assume elements if a Proxy, Special API Object, |
| // or JSValue wrapper is found on the prototype chain. After this |
| // instance type check, it's not necessary to check for interceptors or |
| // access checks. |
| Label if_custom(this, Label::kDeferred), if_notcustom(this); |
| Branch(IsCustomElementsReceiverInstanceType(prototype_instance_type), |
| &if_custom, &if_notcustom); |
| |
| BIND(&if_custom); |
| { |
| // For string JSValue wrappers we still support the checks as long |
| // as they wrap the empty string. |
| GotoIfNot(InstanceTypeEqual(prototype_instance_type, JS_VALUE_TYPE), |
| possibly_elements); |
| Node* prototype_value = LoadJSValueValue(prototype); |
| Branch(IsEmptyString(prototype_value), &if_notcustom, possibly_elements); |
| } |
| |
| BIND(&if_notcustom); |
| { |
| Node* prototype_elements = LoadElements(prototype); |
| var_map.Bind(prototype_map); |
| GotoIf(WordEqual(prototype_elements, empty_fixed_array), &loop_body); |
| Branch(WordEqual(prototype_elements, empty_slow_element_dictionary), |
| &loop_body, possibly_elements); |
| } |
| } |
| } |
| |
| void CodeStubAssembler::BranchIfJSReceiver(Node* object, Label* if_true, |
| Label* if_false) { |
| GotoIf(TaggedIsSmi(object), if_false); |
| STATIC_ASSERT(LAST_JS_RECEIVER_TYPE == LAST_TYPE); |
| Branch(IsJSReceiver(object), if_true, if_false); |
| } |
| |
| void CodeStubAssembler::GotoIfForceSlowPath(Label* if_true) { |
| #ifdef V8_ENABLE_FORCE_SLOW_PATH |
| Node* const force_slow_path_addr = |
| ExternalConstant(ExternalReference::force_slow_path(isolate())); |
| Node* const force_slow = Load(MachineType::Uint8(), force_slow_path_addr); |
| |
| GotoIf(force_slow, if_true); |
| #endif |
| } |
| |
| void CodeStubAssembler::GotoIfDebugExecutionModeChecksSideEffects( |
| Label* if_true) { |
| STATIC_ASSERT(sizeof(DebugInfo::ExecutionMode) >= sizeof(int32_t)); |
| |
| TNode<ExternalReference> execution_mode_address = ExternalConstant( |
| ExternalReference::debug_execution_mode_address(isolate())); |
| TNode<Int32T> execution_mode = |
| UncheckedCast<Int32T>(Load(MachineType::Int32(), execution_mode_address)); |
| |
| GotoIf(Word32Equal(execution_mode, Int32Constant(DebugInfo::kSideEffects)), |
| if_true); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::AllocateRaw(TNode<IntPtrT> size_in_bytes, |
| AllocationFlags flags, |
| TNode<RawPtrT> top_address, |
| TNode<RawPtrT> limit_address) { |
| Label if_out_of_memory(this, Label::kDeferred); |
| |
| // TODO(jgruber,jkummerow): Extract the slow paths (= probably everything |
| // but bump pointer allocation) into a builtin to save code space. The |
| // size_in_bytes check may be moved there as well since a non-smi |
| // size_in_bytes probably doesn't fit into the bump pointer region |
| // (double-check that). |
| |
| intptr_t size_in_bytes_constant; |
| bool size_in_bytes_is_constant = false; |
| if (ToIntPtrConstant(size_in_bytes, size_in_bytes_constant)) { |
| size_in_bytes_is_constant = true; |
| CHECK(Internals::IsValidSmi(size_in_bytes_constant)); |
| CHECK_GT(size_in_bytes_constant, 0); |
| } else { |
| GotoIfNot(IsValidPositiveSmi(size_in_bytes), &if_out_of_memory); |
| } |
| |
| TNode<RawPtrT> top = |
| UncheckedCast<RawPtrT>(Load(MachineType::Pointer(), top_address)); |
| TNode<RawPtrT> limit = |
| UncheckedCast<RawPtrT>(Load(MachineType::Pointer(), limit_address)); |
| |
| // If there's not enough space, call the runtime. |
| TVARIABLE(Object, result); |
| Label runtime_call(this, Label::kDeferred), no_runtime_call(this), out(this); |
| |
| bool needs_double_alignment = flags & kDoubleAlignment; |
| |
| if (flags & kAllowLargeObjectAllocation) { |
| Label next(this); |
| GotoIf(IsRegularHeapObjectSize(size_in_bytes), &next); |
| |
| TNode<Smi> runtime_flags = SmiConstant( |
| Smi::FromInt(AllocateDoubleAlignFlag::encode(needs_double_alignment) | |
| AllocateTargetSpace::encode(AllocationSpace::LO_SPACE))); |
| result = CallRuntime(Runtime::kAllocateInTargetSpace, NoContextConstant(), |
| SmiTag(size_in_bytes), runtime_flags); |
| Goto(&out); |
| |
| BIND(&next); |
| } |
| |
| TVARIABLE(IntPtrT, adjusted_size, size_in_bytes); |
| |
| if (needs_double_alignment) { |
| Label next(this); |
| GotoIfNot(WordAnd(top, IntPtrConstant(kDoubleAlignmentMask)), &next); |
| |
| adjusted_size = IntPtrAdd(size_in_bytes, IntPtrConstant(4)); |
| Goto(&next); |
| |
| BIND(&next); |
| } |
| |
| TNode<IntPtrT> new_top = |
| IntPtrAdd(UncheckedCast<IntPtrT>(top), adjusted_size.value()); |
| |
| Branch(UintPtrGreaterThanOrEqual(new_top, limit), &runtime_call, |
| &no_runtime_call); |
| |
| BIND(&runtime_call); |
| { |
| if (flags & kPretenured) { |
| TNode<Smi> runtime_flags = SmiConstant(Smi::FromInt( |
| AllocateDoubleAlignFlag::encode(needs_double_alignment) | |
| AllocateTargetSpace::encode(AllocationSpace::OLD_SPACE))); |
| result = CallRuntime(Runtime::kAllocateInTargetSpace, NoContextConstant(), |
| SmiTag(size_in_bytes), runtime_flags); |
| } else { |
| result = CallRuntime(Runtime::kAllocateInNewSpace, NoContextConstant(), |
| SmiTag(size_in_bytes)); |
| } |
| Goto(&out); |
| } |
| |
| // When there is enough space, return `top' and bump it up. |
| BIND(&no_runtime_call); |
| { |
| StoreNoWriteBarrier(MachineType::PointerRepresentation(), top_address, |
| new_top); |
| |
| TVARIABLE(IntPtrT, address, UncheckedCast<IntPtrT>(top)); |
| |
| if (needs_double_alignment) { |
| Label next(this); |
| GotoIf(IntPtrEqual(adjusted_size.value(), size_in_bytes), &next); |
| |
| // Store a filler and increase the address by 4. |
| StoreNoWriteBarrier(MachineRepresentation::kTagged, top, |
| LoadRoot(RootIndex::kOnePointerFillerMap)); |
| address = IntPtrAdd(UncheckedCast<IntPtrT>(top), IntPtrConstant(4)); |
| Goto(&next); |
| |
| BIND(&next); |
| } |
| |
| result = BitcastWordToTagged( |
| IntPtrAdd(address.value(), IntPtrConstant(kHeapObjectTag))); |
| Goto(&out); |
| } |
| |
| if (!size_in_bytes_is_constant) { |
| BIND(&if_out_of_memory); |
| CallRuntime(Runtime::kFatalProcessOutOfMemoryInAllocateRaw, |
| NoContextConstant()); |
| Unreachable(); |
| } |
| |
| BIND(&out); |
| return UncheckedCast<HeapObject>(result.value()); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::AllocateRawUnaligned( |
| TNode<IntPtrT> size_in_bytes, AllocationFlags flags, |
| TNode<RawPtrT> top_address, TNode<RawPtrT> limit_address) { |
| DCHECK_EQ(flags & kDoubleAlignment, 0); |
| return AllocateRaw(size_in_bytes, flags, top_address, limit_address); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::AllocateRawDoubleAligned( |
| TNode<IntPtrT> size_in_bytes, AllocationFlags flags, |
| TNode<RawPtrT> top_address, TNode<RawPtrT> limit_address) { |
| #if defined(V8_HOST_ARCH_32_BIT) |
| return AllocateRaw(size_in_bytes, flags | kDoubleAlignment, top_address, |
| limit_address); |
| #elif defined(V8_HOST_ARCH_64_BIT) |
| #ifdef V8_COMPRESS_POINTERS |
| // TODO(ishell, v8:8875): Consider using aligned allocations once the |
| // allocation alignment inconsistency is fixed. For now we keep using |
| // unaligned access since both x64 and arm64 architectures (where pointer |
| // compression is supported) allow unaligned access to doubles and full words. |
| #endif // V8_COMPRESS_POINTERS |
| // Allocation on 64 bit machine is naturally double aligned |
| return AllocateRaw(size_in_bytes, flags & ~kDoubleAlignment, top_address, |
| limit_address); |
| #else |
| #error Architecture not supported |
| #endif |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::AllocateInNewSpace( |
| TNode<IntPtrT> size_in_bytes, AllocationFlags flags) { |
| DCHECK(flags == kNone || flags == kDoubleAlignment); |
| CSA_ASSERT(this, IsRegularHeapObjectSize(size_in_bytes)); |
| return Allocate(size_in_bytes, flags); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::Allocate(TNode<IntPtrT> size_in_bytes, |
| AllocationFlags flags) { |
| Comment("Allocate"); |
| bool const new_space = !(flags & kPretenured); |
| if (!(flags & kAllowLargeObjectAllocation)) { |
| intptr_t size_constant; |
| if (ToIntPtrConstant(size_in_bytes, size_constant)) { |
| CHECK_LE(size_constant, kMaxRegularHeapObjectSize); |
| } |
| } |
| if (!(flags & kDoubleAlignment) && !(flags & kAllowLargeObjectAllocation)) { |
| return OptimizedAllocate(size_in_bytes, new_space |
| ? PretenureFlag::NOT_TENURED |
| : PretenureFlag::TENURED); |
| } |
| TNode<ExternalReference> top_address = ExternalConstant( |
| new_space |
| ? ExternalReference::new_space_allocation_top_address(isolate()) |
| : ExternalReference::old_space_allocation_top_address(isolate())); |
| DCHECK_EQ(kSystemPointerSize, |
| ExternalReference::new_space_allocation_limit_address(isolate()) |
| .address() - |
| ExternalReference::new_space_allocation_top_address(isolate()) |
| .address()); |
| DCHECK_EQ(kSystemPointerSize, |
| ExternalReference::old_space_allocation_limit_address(isolate()) |
| .address() - |
| ExternalReference::old_space_allocation_top_address(isolate()) |
| .address()); |
| TNode<IntPtrT> limit_address = |
| IntPtrAdd(ReinterpretCast<IntPtrT>(top_address), |
| IntPtrConstant(kSystemPointerSize)); |
| |
| if (flags & kDoubleAlignment) { |
| return AllocateRawDoubleAligned(size_in_bytes, flags, |
| ReinterpretCast<RawPtrT>(top_address), |
| ReinterpretCast<RawPtrT>(limit_address)); |
| } else { |
| return AllocateRawUnaligned(size_in_bytes, flags, |
| ReinterpretCast<RawPtrT>(top_address), |
| ReinterpretCast<RawPtrT>(limit_address)); |
| } |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::AllocateInNewSpace(int size_in_bytes, |
| AllocationFlags flags) { |
| CHECK(flags == kNone || flags == kDoubleAlignment); |
| DCHECK_LE(size_in_bytes, kMaxRegularHeapObjectSize); |
| return CodeStubAssembler::Allocate(IntPtrConstant(size_in_bytes), flags); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::Allocate(int size_in_bytes, |
| AllocationFlags flags) { |
| return CodeStubAssembler::Allocate(IntPtrConstant(size_in_bytes), flags); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::InnerAllocate(TNode<HeapObject> previous, |
| TNode<IntPtrT> offset) { |
| return UncheckedCast<HeapObject>( |
| BitcastWordToTagged(IntPtrAdd(BitcastTaggedToWord(previous), offset))); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::InnerAllocate(TNode<HeapObject> previous, |
| int offset) { |
| return InnerAllocate(previous, IntPtrConstant(offset)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsRegularHeapObjectSize(TNode<IntPtrT> size) { |
| return UintPtrLessThanOrEqual(size, |
| IntPtrConstant(kMaxRegularHeapObjectSize)); |
| } |
| |
| void CodeStubAssembler::BranchIfToBooleanIsTrue(Node* value, Label* if_true, |
| Label* if_false) { |
| Label if_smi(this), if_notsmi(this), if_heapnumber(this, Label::kDeferred), |
| if_bigint(this, Label::kDeferred); |
| // Rule out false {value}. |
| GotoIf(WordEqual(value, FalseConstant()), if_false); |
| |
| // Check if {value} is a Smi or a HeapObject. |
| Branch(TaggedIsSmi(value), &if_smi, &if_notsmi); |
| |
| BIND(&if_smi); |
| { |
| // The {value} is a Smi, only need to check against zero. |
| BranchIfSmiEqual(CAST(value), SmiConstant(0), if_false, if_true); |
| } |
| |
| BIND(&if_notsmi); |
| { |
| // Check if {value} is the empty string. |
| GotoIf(IsEmptyString(value), if_false); |
| |
| // The {value} is a HeapObject, load its map. |
| Node* value_map = LoadMap(value); |
| |
| // Only null, undefined and document.all have the undetectable bit set, |
| // so we can return false immediately when that bit is set. |
| GotoIf(IsUndetectableMap(value_map), if_false); |
| |
| // We still need to handle numbers specially, but all other {value}s |
| // that make it here yield true. |
| GotoIf(IsHeapNumberMap(value_map), &if_heapnumber); |
| Branch(IsBigInt(value), &if_bigint, if_true); |
| |
| BIND(&if_heapnumber); |
| { |
| // Load the floating point value of {value}. |
| Node* value_value = LoadObjectField(value, HeapNumber::kValueOffset, |
| MachineType::Float64()); |
| |
| // Check if the floating point {value} is neither 0.0, -0.0 nor NaN. |
| Branch(Float64LessThan(Float64Constant(0.0), Float64Abs(value_value)), |
| if_true, if_false); |
| } |
| |
| BIND(&if_bigint); |
| { |
| Node* result = |
| CallRuntime(Runtime::kBigIntToBoolean, NoContextConstant(), value); |
| CSA_ASSERT(this, IsBoolean(result)); |
| Branch(WordEqual(result, TrueConstant()), if_true, if_false); |
| } |
| } |
| } |
| |
| Node* CodeStubAssembler::LoadFromParentFrame(int offset, MachineType rep) { |
| Node* frame_pointer = LoadParentFramePointer(); |
| return Load(rep, frame_pointer, IntPtrConstant(offset)); |
| } |
| |
| Node* CodeStubAssembler::LoadBufferObject(Node* buffer, int offset, |
| MachineType rep) { |
| return Load(rep, buffer, IntPtrConstant(offset)); |
| } |
| |
| Node* CodeStubAssembler::LoadObjectField(SloppyTNode<HeapObject> object, |
| int offset, MachineType rep) { |
| CSA_ASSERT(this, IsStrong(object)); |
| return Load(rep, object, IntPtrConstant(offset - kHeapObjectTag)); |
| } |
| |
| Node* CodeStubAssembler::LoadObjectField(SloppyTNode<HeapObject> object, |
| SloppyTNode<IntPtrT> offset, |
| MachineType rep) { |
| CSA_ASSERT(this, IsStrong(object)); |
| return Load(rep, object, IntPtrSub(offset, IntPtrConstant(kHeapObjectTag))); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadAndUntagObjectField( |
| SloppyTNode<HeapObject> object, int offset) { |
| if (SmiValuesAre32Bits()) { |
| #if V8_TARGET_LITTLE_ENDIAN |
| offset += 4; |
| #endif |
| return ChangeInt32ToIntPtr( |
| LoadObjectField(object, offset, MachineType::Int32())); |
| } else { |
| return SmiToIntPtr( |
| LoadObjectField(object, offset, MachineType::AnyTagged())); |
| } |
| } |
| |
| TNode<Int32T> CodeStubAssembler::LoadAndUntagToWord32ObjectField(Node* object, |
| int offset) { |
| if (SmiValuesAre32Bits()) { |
| #if V8_TARGET_LITTLE_ENDIAN |
| offset += 4; |
| #endif |
| return UncheckedCast<Int32T>( |
| LoadObjectField(object, offset, MachineType::Int32())); |
| } else { |
| return SmiToInt32( |
| LoadObjectField(object, offset, MachineType::AnyTagged())); |
| } |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadAndUntagSmi(Node* base, int index) { |
| if (SmiValuesAre32Bits()) { |
| #if V8_TARGET_LITTLE_ENDIAN |
| index += 4; |
| #endif |
| return ChangeInt32ToIntPtr( |
| Load(MachineType::Int32(), base, IntPtrConstant(index))); |
| } else { |
| return SmiToIntPtr( |
| Load(MachineType::AnyTagged(), base, IntPtrConstant(index))); |
| } |
| } |
| |
| void CodeStubAssembler::StoreAndTagSmi(Node* base, int offset, Node* value) { |
| if (SmiValuesAre32Bits()) { |
| int zero_offset = offset + 4; |
| int payload_offset = offset; |
| #if V8_TARGET_LITTLE_ENDIAN |
| std::swap(zero_offset, payload_offset); |
| #endif |
| StoreNoWriteBarrier(MachineRepresentation::kWord32, base, |
| IntPtrConstant(zero_offset), Int32Constant(0)); |
| StoreNoWriteBarrier(MachineRepresentation::kWord32, base, |
| IntPtrConstant(payload_offset), |
| TruncateInt64ToInt32(value)); |
| } else { |
| StoreNoWriteBarrier(MachineRepresentation::kTaggedSigned, base, |
| IntPtrConstant(offset), SmiTag(value)); |
| } |
| } |
| |
| TNode<Float64T> CodeStubAssembler::LoadHeapNumberValue( |
| SloppyTNode<HeapNumber> object) { |
| return TNode<Float64T>::UncheckedCast(LoadObjectField( |
| object, HeapNumber::kValueOffset, MachineType::Float64())); |
| } |
| |
| TNode<Map> CodeStubAssembler::LoadMap(SloppyTNode<HeapObject> object) { |
| return UncheckedCast<Map>(LoadObjectField(object, HeapObject::kMapOffset, |
| MachineType::TaggedPointer())); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::LoadInstanceType( |
| SloppyTNode<HeapObject> object) { |
| return LoadMapInstanceType(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::HasInstanceType(SloppyTNode<HeapObject> object, |
| InstanceType instance_type) { |
| return InstanceTypeEqual(LoadInstanceType(object), instance_type); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::DoesntHaveInstanceType( |
| SloppyTNode<HeapObject> object, InstanceType instance_type) { |
| return Word32NotEqual(LoadInstanceType(object), Int32Constant(instance_type)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::TaggedDoesntHaveInstanceType( |
| SloppyTNode<HeapObject> any_tagged, InstanceType type) { |
| /* return Phi <TaggedIsSmi(val), DoesntHaveInstanceType(val, type)> */ |
| TNode<BoolT> tagged_is_smi = TaggedIsSmi(any_tagged); |
| return Select<BoolT>( |
| tagged_is_smi, [=]() { return tagged_is_smi; }, |
| [=]() { return DoesntHaveInstanceType(any_tagged, type); }); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::LoadFastProperties( |
| SloppyTNode<JSObject> object) { |
| CSA_SLOW_ASSERT(this, Word32BinaryNot(IsDictionaryMap(LoadMap(object)))); |
| TNode<Object> properties = LoadJSReceiverPropertiesOrHash(object); |
| return Select<HeapObject>(TaggedIsSmi(properties), |
| [=] { return EmptyFixedArrayConstant(); }, |
| [=] { return CAST(properties); }); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::LoadSlowProperties( |
| SloppyTNode<JSObject> object) { |
| CSA_SLOW_ASSERT(this, IsDictionaryMap(LoadMap(object))); |
| TNode<Object> properties = LoadJSReceiverPropertiesOrHash(object); |
| return Select<HeapObject>(TaggedIsSmi(properties), |
| [=] { return EmptyPropertyDictionaryConstant(); }, |
| [=] { return CAST(properties); }); |
| } |
| |
| TNode<Number> CodeStubAssembler::LoadJSArrayLength(SloppyTNode<JSArray> array) { |
| CSA_ASSERT(this, IsJSArray(array)); |
| return CAST(LoadObjectField(array, JSArray::kLengthOffset)); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadJSArgumentsObjectWithLength( |
| SloppyTNode<JSArgumentsObjectWithLength> array) { |
| return LoadObjectField(array, JSArgumentsObjectWithLength::kLengthOffset); |
| } |
| |
| TNode<Smi> CodeStubAssembler::LoadFastJSArrayLength( |
| SloppyTNode<JSArray> array) { |
| TNode<Object> length = LoadJSArrayLength(array); |
| CSA_ASSERT(this, IsFastElementsKind(LoadElementsKind(array))); |
| // JSArray length is always a positive Smi for fast arrays. |
| CSA_SLOW_ASSERT(this, TaggedIsPositiveSmi(length)); |
| return UncheckedCast<Smi>(length); |
| } |
| |
| TNode<Smi> CodeStubAssembler::LoadFixedArrayBaseLength( |
| SloppyTNode<FixedArrayBase> array) { |
| CSA_SLOW_ASSERT(this, IsNotWeakFixedArraySubclass(array)); |
| return CAST(LoadObjectField(array, FixedArrayBase::kLengthOffset)); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadAndUntagFixedArrayBaseLength( |
| SloppyTNode<FixedArrayBase> array) { |
| return LoadAndUntagObjectField(array, FixedArrayBase::kLengthOffset); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadFeedbackVectorLength( |
| TNode<FeedbackVector> vector) { |
| return ChangeInt32ToIntPtr( |
| LoadObjectField<Int32T>(vector, FeedbackVector::kLengthOffset)); |
| } |
| |
| TNode<Smi> CodeStubAssembler::LoadWeakFixedArrayLength( |
| TNode<WeakFixedArray> array) { |
| return CAST(LoadObjectField(array, WeakFixedArray::kLengthOffset)); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadAndUntagWeakFixedArrayLength( |
| SloppyTNode<WeakFixedArray> array) { |
| return LoadAndUntagObjectField(array, WeakFixedArray::kLengthOffset); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::LoadNumberOfDescriptors( |
| TNode<DescriptorArray> array) { |
| return UncheckedCast<Int32T>( |
| LoadObjectField(array, DescriptorArray::kNumberOfDescriptorsOffset, |
| MachineType::Int16())); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::LoadMapBitField(SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| return UncheckedCast<Int32T>( |
| LoadObjectField(map, Map::kBitFieldOffset, MachineType::Uint8())); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::LoadMapBitField2(SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| return UncheckedCast<Int32T>( |
| LoadObjectField(map, Map::kBitField2Offset, MachineType::Uint8())); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::LoadMapBitField3(SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| return UncheckedCast<Uint32T>( |
| LoadObjectField(map, Map::kBitField3Offset, MachineType::Uint32())); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::LoadMapInstanceType(SloppyTNode<Map> map) { |
| return UncheckedCast<Int32T>( |
| LoadObjectField(map, Map::kInstanceTypeOffset, MachineType::Uint16())); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::LoadMapElementsKind(SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| Node* bit_field2 = LoadMapBitField2(map); |
| return Signed(DecodeWord32<Map::ElementsKindBits>(bit_field2)); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::LoadElementsKind( |
| SloppyTNode<HeapObject> object) { |
| return LoadMapElementsKind(LoadMap(object)); |
| } |
| |
| TNode<DescriptorArray> CodeStubAssembler::LoadMapDescriptors( |
| SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| return CAST(LoadObjectField(map, Map::kDescriptorsOffset)); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::LoadMapPrototype(SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| return CAST(LoadObjectField(map, Map::kPrototypeOffset)); |
| } |
| |
| TNode<PrototypeInfo> CodeStubAssembler::LoadMapPrototypeInfo( |
| SloppyTNode<Map> map, Label* if_no_proto_info) { |
| Label if_strong_heap_object(this); |
| CSA_ASSERT(this, IsMap(map)); |
| TNode<MaybeObject> maybe_prototype_info = |
| LoadMaybeWeakObjectField(map, Map::kTransitionsOrPrototypeInfoOffset); |
| TVARIABLE(Object, prototype_info); |
| DispatchMaybeObject(maybe_prototype_info, if_no_proto_info, if_no_proto_info, |
| if_no_proto_info, &if_strong_heap_object, |
| &prototype_info); |
| |
| BIND(&if_strong_heap_object); |
| GotoIfNot(WordEqual(LoadMap(CAST(prototype_info.value())), |
| LoadRoot(RootIndex::kPrototypeInfoMap)), |
| if_no_proto_info); |
| return CAST(prototype_info.value()); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadMapInstanceSizeInWords( |
| SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| return ChangeInt32ToIntPtr(LoadObjectField( |
| map, Map::kInstanceSizeInWordsOffset, MachineType::Uint8())); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadMapInobjectPropertiesStartInWords( |
| SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| // See Map::GetInObjectPropertiesStartInWords() for details. |
| CSA_ASSERT(this, IsJSObjectMap(map)); |
| return ChangeInt32ToIntPtr(LoadObjectField( |
| map, Map::kInObjectPropertiesStartOrConstructorFunctionIndexOffset, |
| MachineType::Uint8())); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadMapConstructorFunctionIndex( |
| SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| // See Map::GetConstructorFunctionIndex() for details. |
| CSA_ASSERT(this, IsPrimitiveInstanceType(LoadMapInstanceType(map))); |
| return ChangeInt32ToIntPtr(LoadObjectField( |
| map, Map::kInObjectPropertiesStartOrConstructorFunctionIndexOffset, |
| MachineType::Uint8())); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadMapConstructor(SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| TVARIABLE(Object, result, |
| LoadObjectField(map, Map::kConstructorOrBackPointerOffset)); |
| |
| Label done(this), loop(this, &result); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| GotoIf(TaggedIsSmi(result.value()), &done); |
| Node* is_map_type = |
| InstanceTypeEqual(LoadInstanceType(CAST(result.value())), MAP_TYPE); |
| GotoIfNot(is_map_type, &done); |
| result = LoadObjectField(CAST(result.value()), |
| Map::kConstructorOrBackPointerOffset); |
| Goto(&loop); |
| } |
| BIND(&done); |
| return result.value(); |
| } |
| |
| Node* CodeStubAssembler::LoadMapEnumLength(SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| Node* bit_field3 = LoadMapBitField3(map); |
| return DecodeWordFromWord32<Map::EnumLengthBits>(bit_field3); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadMapBackPointer(SloppyTNode<Map> map) { |
| TNode<HeapObject> object = |
| CAST(LoadObjectField(map, Map::kConstructorOrBackPointerOffset)); |
| return Select<Object>(IsMap(object), [=] { return object; }, |
| [=] { return UndefinedConstant(); }); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::EnsureOnlyHasSimpleProperties( |
| TNode<Map> map, TNode<Int32T> instance_type, Label* bailout) { |
| // This check can have false positives, since it applies to any JSValueType. |
| GotoIf(IsCustomElementsReceiverInstanceType(instance_type), bailout); |
| |
| TNode<Uint32T> bit_field3 = LoadMapBitField3(map); |
| GotoIf(IsSetWord32(bit_field3, Map::IsDictionaryMapBit::kMask | |
| Map::HasHiddenPrototypeBit::kMask), |
| bailout); |
| |
| return bit_field3; |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadJSReceiverIdentityHash( |
| SloppyTNode<Object> receiver, Label* if_no_hash) { |
| TVARIABLE(IntPtrT, var_hash); |
| Label done(this), if_smi(this), if_property_array(this), |
| if_property_dictionary(this), if_fixed_array(this); |
| |
| TNode<Object> properties_or_hash = |
| LoadObjectField(TNode<HeapObject>::UncheckedCast(receiver), |
| JSReceiver::kPropertiesOrHashOffset); |
| GotoIf(TaggedIsSmi(properties_or_hash), &if_smi); |
| |
| TNode<HeapObject> properties = |
| TNode<HeapObject>::UncheckedCast(properties_or_hash); |
| TNode<Int32T> properties_instance_type = LoadInstanceType(properties); |
| |
| GotoIf(InstanceTypeEqual(properties_instance_type, PROPERTY_ARRAY_TYPE), |
| &if_property_array); |
| Branch(InstanceTypeEqual(properties_instance_type, NAME_DICTIONARY_TYPE), |
| &if_property_dictionary, &if_fixed_array); |
| |
| BIND(&if_fixed_array); |
| { |
| var_hash = IntPtrConstant(PropertyArray::kNoHashSentinel); |
| Goto(&done); |
| } |
| |
| BIND(&if_smi); |
| { |
| var_hash = SmiUntag(TNode<Smi>::UncheckedCast(properties_or_hash)); |
| Goto(&done); |
| } |
| |
| BIND(&if_property_array); |
| { |
| TNode<IntPtrT> length_and_hash = LoadAndUntagObjectField( |
| properties, PropertyArray::kLengthAndHashOffset); |
| var_hash = TNode<IntPtrT>::UncheckedCast( |
| DecodeWord<PropertyArray::HashField>(length_and_hash)); |
| Goto(&done); |
| } |
| |
| BIND(&if_property_dictionary); |
| { |
| var_hash = SmiUntag(CAST(LoadFixedArrayElement( |
| CAST(properties), NameDictionary::kObjectHashIndex))); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| if (if_no_hash != nullptr) { |
| GotoIf(IntPtrEqual(var_hash.value(), |
| IntPtrConstant(PropertyArray::kNoHashSentinel)), |
| if_no_hash); |
| } |
| return var_hash.value(); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::LoadNameHashField(SloppyTNode<Name> name) { |
| CSA_ASSERT(this, IsName(name)); |
| return LoadObjectField<Uint32T>(name, Name::kHashFieldOffset); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::LoadNameHash(SloppyTNode<Name> name, |
| Label* if_hash_not_computed) { |
| TNode<Uint32T> hash_field = LoadNameHashField(name); |
| if (if_hash_not_computed != nullptr) { |
| GotoIf(IsSetWord32(hash_field, Name::kHashNotComputedMask), |
| if_hash_not_computed); |
| } |
| return Unsigned(Word32Shr(hash_field, Int32Constant(Name::kHashShift))); |
| } |
| |
| TNode<Smi> CodeStubAssembler::LoadStringLengthAsSmi( |
| SloppyTNode<String> string) { |
| return SmiFromIntPtr(LoadStringLengthAsWord(string)); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadStringLengthAsWord( |
| SloppyTNode<String> string) { |
| return Signed(ChangeUint32ToWord(LoadStringLengthAsWord32(string))); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::LoadStringLengthAsWord32( |
| SloppyTNode<String> string) { |
| CSA_ASSERT(this, IsString(string)); |
| return LoadObjectField<Uint32T>(string, String::kLengthOffset); |
| } |
| |
| Node* CodeStubAssembler::PointerToSeqStringData(Node* seq_string) { |
| CSA_ASSERT(this, IsString(seq_string)); |
| CSA_ASSERT(this, |
| IsSequentialStringInstanceType(LoadInstanceType(seq_string))); |
| STATIC_ASSERT(SeqOneByteString::kHeaderSize == SeqTwoByteString::kHeaderSize); |
| return IntPtrAdd( |
| BitcastTaggedToWord(seq_string), |
| IntPtrConstant(SeqOneByteString::kHeaderSize - kHeapObjectTag)); |
| } |
| |
| Node* CodeStubAssembler::LoadJSValueValue(Node* object) { |
| CSA_ASSERT(this, IsJSValue(object)); |
| return LoadObjectField(object, JSValue::kValueOffset); |
| } |
| |
| void CodeStubAssembler::DispatchMaybeObject(TNode<MaybeObject> maybe_object, |
| Label* if_smi, Label* if_cleared, |
| Label* if_weak, Label* if_strong, |
| TVariable<Object>* extracted) { |
| Label inner_if_smi(this), inner_if_strong(this); |
| |
| GotoIf(TaggedIsSmi(maybe_object), &inner_if_smi); |
| |
| GotoIf(IsCleared(maybe_object), if_cleared); |
| |
| GotoIf(Word32Equal(Word32And(TruncateIntPtrToInt32( |
| BitcastMaybeObjectToWord(maybe_object)), |
| Int32Constant(kHeapObjectTagMask)), |
| Int32Constant(kHeapObjectTag)), |
| &inner_if_strong); |
| |
| *extracted = |
| BitcastWordToTagged(WordAnd(BitcastMaybeObjectToWord(maybe_object), |
| IntPtrConstant(~kWeakHeapObjectMask))); |
| Goto(if_weak); |
| |
| BIND(&inner_if_smi); |
| *extracted = CAST(maybe_object); |
| Goto(if_smi); |
| |
| BIND(&inner_if_strong); |
| *extracted = CAST(maybe_object); |
| Goto(if_strong); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsStrong(TNode<MaybeObject> value) { |
| return WordEqual(WordAnd(BitcastMaybeObjectToWord(value), |
| IntPtrConstant(kHeapObjectTagMask)), |
| IntPtrConstant(kHeapObjectTag)); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::GetHeapObjectIfStrong( |
| TNode<MaybeObject> value, Label* if_not_strong) { |
| GotoIfNot(IsStrong(value), if_not_strong); |
| return CAST(value); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsWeakOrCleared(TNode<MaybeObject> value) { |
| return Word32Equal( |
| Word32And(TruncateIntPtrToInt32(BitcastMaybeObjectToWord(value)), |
| Int32Constant(kHeapObjectTagMask)), |
| Int32Constant(kWeakHeapObjectTag)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsCleared(TNode<MaybeObject> value) { |
| return Word32Equal(TruncateIntPtrToInt32(BitcastMaybeObjectToWord(value)), |
| Int32Constant(kClearedWeakHeapObjectLower32)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNotCleared(TNode<MaybeObject> value) { |
| return Word32NotEqual(TruncateIntPtrToInt32(BitcastMaybeObjectToWord(value)), |
| Int32Constant(kClearedWeakHeapObjectLower32)); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::GetHeapObjectAssumeWeak( |
| TNode<MaybeObject> value) { |
| CSA_ASSERT(this, IsWeakOrCleared(value)); |
| CSA_ASSERT(this, IsNotCleared(value)); |
| return UncheckedCast<HeapObject>(BitcastWordToTagged(WordAnd( |
| BitcastMaybeObjectToWord(value), IntPtrConstant(~kWeakHeapObjectMask)))); |
| } |
| |
| TNode<HeapObject> CodeStubAssembler::GetHeapObjectAssumeWeak( |
| TNode<MaybeObject> value, Label* if_cleared) { |
| GotoIf(IsCleared(value), if_cleared); |
| return GetHeapObjectAssumeWeak(value); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsWeakReferenceTo(TNode<MaybeObject> object, |
| TNode<Object> value) { |
| return WordEqual(WordAnd(BitcastMaybeObjectToWord(object), |
| IntPtrConstant(~kWeakHeapObjectMask)), |
| BitcastTaggedToWord(value)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsStrongReferenceTo(TNode<MaybeObject> object, |
| TNode<Object> value) { |
| return WordEqual(BitcastMaybeObjectToWord(object), |
| BitcastTaggedToWord(value)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNotWeakReferenceTo(TNode<MaybeObject> object, |
| TNode<Object> value) { |
| return WordNotEqual(WordAnd(BitcastMaybeObjectToWord(object), |
| IntPtrConstant(~kWeakHeapObjectMask)), |
| BitcastTaggedToWord(value)); |
| } |
| |
| TNode<MaybeObject> CodeStubAssembler::MakeWeak(TNode<HeapObject> value) { |
| return ReinterpretCast<MaybeObject>(BitcastWordToTagged( |
| WordOr(BitcastTaggedToWord(value), IntPtrConstant(kWeakHeapObjectTag)))); |
| } |
| |
| template <> |
| TNode<IntPtrT> CodeStubAssembler::LoadArrayLength(TNode<FixedArray> array) { |
| return LoadAndUntagFixedArrayBaseLength(array); |
| } |
| |
| template <> |
| TNode<IntPtrT> CodeStubAssembler::LoadArrayLength(TNode<WeakFixedArray> array) { |
| return LoadAndUntagWeakFixedArrayLength(array); |
| } |
| |
| template <> |
| TNode<IntPtrT> CodeStubAssembler::LoadArrayLength(TNode<PropertyArray> array) { |
| return LoadPropertyArrayLength(array); |
| } |
| |
| template <> |
| TNode<IntPtrT> CodeStubAssembler::LoadArrayLength( |
| TNode<DescriptorArray> array) { |
| return IntPtrMul(ChangeInt32ToIntPtr(LoadNumberOfDescriptors(array)), |
| IntPtrConstant(DescriptorArray::kEntrySize)); |
| } |
| |
| template <> |
| TNode<IntPtrT> CodeStubAssembler::LoadArrayLength( |
| TNode<TransitionArray> array) { |
| return LoadAndUntagWeakFixedArrayLength(array); |
| } |
| |
| template <typename Array> |
| TNode<MaybeObject> CodeStubAssembler::LoadArrayElement( |
| TNode<Array> array, int array_header_size, Node* index_node, |
| int additional_offset, ParameterMode parameter_mode, |
| LoadSensitivity needs_poisoning) { |
| CSA_ASSERT(this, IntPtrGreaterThanOrEqual( |
| ParameterToIntPtr(index_node, parameter_mode), |
| IntPtrConstant(0))); |
| DCHECK(IsAligned(additional_offset, kTaggedSize)); |
| int32_t header_size = array_header_size + additional_offset - kHeapObjectTag; |
| TNode<IntPtrT> offset = ElementOffsetFromIndex(index_node, HOLEY_ELEMENTS, |
| parameter_mode, header_size); |
| CSA_ASSERT(this, IsOffsetInBounds(offset, LoadArrayLength(array), |
| array_header_size)); |
| return UncheckedCast<MaybeObject>( |
| Load(MachineType::AnyTagged(), array, offset, needs_poisoning)); |
| } |
| |
| template TNode<MaybeObject> |
| CodeStubAssembler::LoadArrayElement<TransitionArray>(TNode<TransitionArray>, |
| int, Node*, int, |
| ParameterMode, |
| LoadSensitivity); |
| |
| template TNode<MaybeObject> |
| CodeStubAssembler::LoadArrayElement<DescriptorArray>(TNode<DescriptorArray>, |
| int, Node*, int, |
| ParameterMode, |
| LoadSensitivity); |
| |
| void CodeStubAssembler::FixedArrayBoundsCheck(TNode<FixedArrayBase> array, |
| Node* index, |
| int additional_offset, |
| ParameterMode parameter_mode) { |
| if (!FLAG_fixed_array_bounds_checks) return; |
| DCHECK(IsAligned(additional_offset, kTaggedSize)); |
| if (parameter_mode == ParameterMode::SMI_PARAMETERS) { |
| TNode<Smi> effective_index; |
| Smi constant_index; |
| bool index_is_constant = ToSmiConstant(index, &constant_index); |
| if (index_is_constant) { |
| effective_index = SmiConstant(Smi::ToInt(constant_index) + |
| additional_offset / kTaggedSize); |
| } else if (additional_offset != 0) { |
| effective_index = |
| SmiAdd(CAST(index), SmiConstant(additional_offset / kTaggedSize)); |
| } else { |
| effective_index = CAST(index); |
| } |
| CSA_CHECK(this, SmiBelow(effective_index, LoadFixedArrayBaseLength(array))); |
| } else { |
| // IntPtrAdd does constant-folding automatically. |
| TNode<IntPtrT> effective_index = |
| IntPtrAdd(UncheckedCast<IntPtrT>(index), |
| IntPtrConstant(additional_offset / kTaggedSize)); |
| CSA_CHECK(this, UintPtrLessThan(effective_index, |
| LoadAndUntagFixedArrayBaseLength(array))); |
| } |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadFixedArrayElement( |
| TNode<FixedArray> object, Node* index_node, int additional_offset, |
| ParameterMode parameter_mode, LoadSensitivity needs_poisoning, |
| CheckBounds check_bounds) { |
| CSA_ASSERT(this, IsFixedArraySubclass(object)); |
| CSA_ASSERT(this, IsNotWeakFixedArraySubclass(object)); |
| if (NeedsBoundsCheck(check_bounds)) { |
| FixedArrayBoundsCheck(object, index_node, additional_offset, |
| parameter_mode); |
| } |
| TNode<MaybeObject> element = |
| LoadArrayElement(object, FixedArray::kHeaderSize, index_node, |
| additional_offset, parameter_mode, needs_poisoning); |
| return CAST(element); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadPropertyArrayElement( |
| TNode<PropertyArray> object, SloppyTNode<IntPtrT> index) { |
| int additional_offset = 0; |
| ParameterMode parameter_mode = INTPTR_PARAMETERS; |
| LoadSensitivity needs_poisoning = LoadSensitivity::kSafe; |
| return CAST(LoadArrayElement(object, PropertyArray::kHeaderSize, index, |
| additional_offset, parameter_mode, |
| needs_poisoning)); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::LoadPropertyArrayLength( |
| TNode<PropertyArray> object) { |
| TNode<IntPtrT> value = |
| LoadAndUntagObjectField(object, PropertyArray::kLengthAndHashOffset); |
| return Signed(DecodeWord<PropertyArray::LengthField>(value)); |
| } |
| |
| TNode<RawPtrT> CodeStubAssembler::LoadFixedTypedArrayBackingStore( |
| TNode<FixedTypedArrayBase> typed_array) { |
| // Backing store = external_pointer + base_pointer. |
| Node* external_pointer = |
| LoadObjectField(typed_array, FixedTypedArrayBase::kExternalPointerOffset, |
| MachineType::Pointer()); |
| Node* base_pointer = |
| LoadObjectField(typed_array, FixedTypedArrayBase::kBasePointerOffset); |
| return UncheckedCast<RawPtrT>( |
| IntPtrAdd(external_pointer, BitcastTaggedToWord(base_pointer))); |
| } |
| |
| TNode<RawPtrT> CodeStubAssembler::LoadFixedTypedArrayOnHeapBackingStore( |
| TNode<FixedTypedArrayBase> typed_array) { |
| // This is specialized method of retrieving the backing store pointer for on |
| // heap allocated typed array buffer. On heap allocated buffer's backing |
| // stores are a fixed offset from the pointer to a typed array's elements. See |
| // TypedArrayBuiltinsAssembler::AllocateOnHeapElements(). |
| TNode<WordT> backing_store = |
| IntPtrAdd(BitcastTaggedToWord(typed_array), |
| IntPtrConstant( |
| FixedTypedArrayBase::ExternalPointerValueForOnHeapArray())); |
| |
| #ifdef DEBUG |
| // Verify that this is an on heap backing store. |
| TNode<RawPtrT> expected_backing_store_pointer = |
| LoadFixedTypedArrayBackingStore(typed_array); |
| CSA_ASSERT(this, WordEqual(backing_store, expected_backing_store_pointer)); |
| #endif |
| |
| return UncheckedCast<RawPtrT>(backing_store); |
| } |
| |
| Node* CodeStubAssembler::LoadFixedBigInt64ArrayElementAsTagged( |
| Node* data_pointer, Node* offset) { |
| if (Is64()) { |
| TNode<IntPtrT> value = UncheckedCast<IntPtrT>( |
| Load(MachineType::IntPtr(), data_pointer, offset)); |
| return BigIntFromInt64(value); |
| } else { |
| DCHECK(!Is64()); |
| #if defined(V8_TARGET_BIG_ENDIAN) |
| TNode<IntPtrT> high = UncheckedCast<IntPtrT>( |
| Load(MachineType::UintPtr(), data_pointer, offset)); |
| TNode<IntPtrT> low = UncheckedCast<IntPtrT>( |
| Load(MachineType::UintPtr(), data_pointer, |
| Int32Add(offset, Int32Constant(kSystemPointerSize)))); |
| #else |
| TNode<IntPtrT> low = UncheckedCast<IntPtrT>( |
| Load(MachineType::UintPtr(), data_pointer, offset)); |
| TNode<IntPtrT> high = UncheckedCast<IntPtrT>( |
| Load(MachineType::UintPtr(), data_pointer, |
| Int32Add(offset, Int32Constant(kSystemPointerSize)))); |
| #endif |
| return BigIntFromInt32Pair(low, high); |
| } |
| } |
| |
| TNode<BigInt> CodeStubAssembler::BigIntFromInt32Pair(TNode<IntPtrT> low, |
| TNode<IntPtrT> high) { |
| DCHECK(!Is64()); |
| TVARIABLE(BigInt, var_result); |
| TVARIABLE(Word32T, var_sign, Int32Constant(BigInt::SignBits::encode(false))); |
| TVARIABLE(IntPtrT, var_high, high); |
| TVARIABLE(IntPtrT, var_low, low); |
| Label high_zero(this), negative(this), allocate_one_digit(this), |
| allocate_two_digits(this), if_zero(this), done(this); |
| |
| GotoIf(WordEqual(var_high.value(), IntPtrConstant(0)), &high_zero); |
| Branch(IntPtrLessThan(var_high.value(), IntPtrConstant(0)), &negative, |
| &allocate_two_digits); |
| |
| BIND(&high_zero); |
| Branch(WordEqual(var_low.value(), IntPtrConstant(0)), &if_zero, |
| &allocate_one_digit); |
| |
| BIND(&negative); |
| { |
| var_sign = Int32Constant(BigInt::SignBits::encode(true)); |
| // We must negate the value by computing "0 - (high|low)", performing |
| // both parts of the subtraction separately and manually taking care |
| // of the carry bit (which is 1 iff low != 0). |
| var_high = IntPtrSub(IntPtrConstant(0), var_high.value()); |
| Label carry(this), no_carry(this); |
| Branch(WordEqual(var_low.value(), IntPtrConstant(0)), &no_carry, &carry); |
| BIND(&carry); |
| var_high = IntPtrSub(var_high.value(), IntPtrConstant(1)); |
| Goto(&no_carry); |
| BIND(&no_carry); |
| var_low = IntPtrSub(IntPtrConstant(0), var_low.value()); |
| // var_high was non-zero going into this block, but subtracting the |
| // carry bit from it could bring us back onto the "one digit" path. |
| Branch(WordEqual(var_high.value(), IntPtrConstant(0)), &allocate_one_digit, |
| &allocate_two_digits); |
| } |
| |
| BIND(&allocate_one_digit); |
| { |
| var_result = AllocateRawBigInt(IntPtrConstant(1)); |
| StoreBigIntBitfield(var_result.value(), |
| Word32Or(var_sign.value(), |
| Int32Constant(BigInt::LengthBits::encode(1)))); |
| StoreBigIntDigit(var_result.value(), 0, Unsigned(var_low.value())); |
| Goto(&done); |
| } |
| |
| BIND(&allocate_two_digits); |
| { |
| var_result = AllocateRawBigInt(IntPtrConstant(2)); |
| StoreBigIntBitfield(var_result.value(), |
| Word32Or(var_sign.value(), |
| Int32Constant(BigInt::LengthBits::encode(2)))); |
| StoreBigIntDigit(var_result.value(), 0, Unsigned(var_low.value())); |
| StoreBigIntDigit(var_result.value(), 1, Unsigned(var_high.value())); |
| Goto(&done); |
| } |
| |
| BIND(&if_zero); |
| var_result = AllocateBigInt(IntPtrConstant(0)); |
| Goto(&done); |
| |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| TNode<BigInt> CodeStubAssembler::BigIntFromInt64(TNode<IntPtrT> value) { |
| DCHECK(Is64()); |
| TVARIABLE(BigInt, var_result); |
| Label done(this), if_positive(this), if_negative(this), if_zero(this); |
| GotoIf(WordEqual(value, IntPtrConstant(0)), &if_zero); |
| var_result = AllocateRawBigInt(IntPtrConstant(1)); |
| Branch(IntPtrGreaterThan(value, IntPtrConstant(0)), &if_positive, |
| &if_negative); |
| |
| BIND(&if_positive); |
| { |
| StoreBigIntBitfield(var_result.value(), |
| Int32Constant(BigInt::SignBits::encode(false) | |
| BigInt::LengthBits::encode(1))); |
| StoreBigIntDigit(var_result.value(), 0, Unsigned(value)); |
| Goto(&done); |
| } |
| |
| BIND(&if_negative); |
| { |
| StoreBigIntBitfield(var_result.value(), |
| Int32Constant(BigInt::SignBits::encode(true) | |
| BigInt::LengthBits::encode(1))); |
| StoreBigIntDigit(var_result.value(), 0, |
| Unsigned(IntPtrSub(IntPtrConstant(0), value))); |
| Goto(&done); |
| } |
| |
| BIND(&if_zero); |
| { |
| var_result = AllocateBigInt(IntPtrConstant(0)); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| Node* CodeStubAssembler::LoadFixedBigUint64ArrayElementAsTagged( |
| Node* data_pointer, Node* offset) { |
| Label if_zero(this), done(this); |
| if (Is64()) { |
| TNode<UintPtrT> value = UncheckedCast<UintPtrT>( |
| Load(MachineType::UintPtr(), data_pointer, offset)); |
| return BigIntFromUint64(value); |
| } else { |
| DCHECK(!Is64()); |
| #if defined(V8_TARGET_BIG_ENDIAN) |
| TNode<UintPtrT> high = UncheckedCast<UintPtrT>( |
| Load(MachineType::UintPtr(), data_pointer, offset)); |
| TNode<UintPtrT> low = UncheckedCast<UintPtrT>( |
| Load(MachineType::UintPtr(), data_pointer, |
| Int32Add(offset, Int32Constant(kSystemPointerSize)))); |
| #else |
| TNode<UintPtrT> low = UncheckedCast<UintPtrT>( |
| Load(MachineType::UintPtr(), data_pointer, offset)); |
| TNode<UintPtrT> high = UncheckedCast<UintPtrT>( |
| Load(MachineType::UintPtr(), data_pointer, |
| Int32Add(offset, Int32Constant(kSystemPointerSize)))); |
| #endif |
| return BigIntFromUint32Pair(low, high); |
| } |
| } |
| |
| TNode<BigInt> CodeStubAssembler::BigIntFromUint32Pair(TNode<UintPtrT> low, |
| TNode<UintPtrT> high) { |
| DCHECK(!Is64()); |
| TVARIABLE(BigInt, var_result); |
| Label high_zero(this), if_zero(this), done(this); |
| |
| GotoIf(WordEqual(high, IntPtrConstant(0)), &high_zero); |
| var_result = AllocateBigInt(IntPtrConstant(2)); |
| StoreBigIntDigit(var_result.value(), 0, low); |
| StoreBigIntDigit(var_result.value(), 1, high); |
| Goto(&done); |
| |
| BIND(&high_zero); |
| GotoIf(WordEqual(low, IntPtrConstant(0)), &if_zero); |
| var_result = AllocateBigInt(IntPtrConstant(1)); |
| StoreBigIntDigit(var_result.value(), 0, low); |
| Goto(&done); |
| |
| BIND(&if_zero); |
| var_result = AllocateBigInt(IntPtrConstant(0)); |
| Goto(&done); |
| |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| TNode<BigInt> CodeStubAssembler::BigIntFromUint64(TNode<UintPtrT> value) { |
| DCHECK(Is64()); |
| TVARIABLE(BigInt, var_result); |
| Label done(this), if_zero(this); |
| GotoIf(WordEqual(value, IntPtrConstant(0)), &if_zero); |
| var_result = AllocateBigInt(IntPtrConstant(1)); |
| StoreBigIntDigit(var_result.value(), 0, value); |
| Goto(&done); |
| |
| BIND(&if_zero); |
| var_result = AllocateBigInt(IntPtrConstant(0)); |
| Goto(&done); |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| Node* CodeStubAssembler::LoadFixedTypedArrayElementAsTagged( |
| Node* data_pointer, Node* index_node, ElementsKind elements_kind, |
| ParameterMode parameter_mode) { |
| Node* offset = |
| ElementOffsetFromIndex(index_node, elements_kind, parameter_mode, 0); |
| switch (elements_kind) { |
| case UINT8_ELEMENTS: /* fall through */ |
| case UINT8_CLAMPED_ELEMENTS: |
| return SmiFromInt32(Load(MachineType::Uint8(), data_pointer, offset)); |
| case INT8_ELEMENTS: |
| return SmiFromInt32(Load(MachineType::Int8(), data_pointer, offset)); |
| case UINT16_ELEMENTS: |
| return SmiFromInt32(Load(MachineType::Uint16(), data_pointer, offset)); |
| case INT16_ELEMENTS: |
| return SmiFromInt32(Load(MachineType::Int16(), data_pointer, offset)); |
| case UINT32_ELEMENTS: |
| return ChangeUint32ToTagged( |
| Load(MachineType::Uint32(), data_pointer, offset)); |
| case INT32_ELEMENTS: |
| return ChangeInt32ToTagged( |
| Load(MachineType::Int32(), data_pointer, offset)); |
| case FLOAT32_ELEMENTS: |
| return AllocateHeapNumberWithValue(ChangeFloat32ToFloat64( |
| Load(MachineType::Float32(), data_pointer, offset))); |
| case FLOAT64_ELEMENTS: |
| return AllocateHeapNumberWithValue( |
| Load(MachineType::Float64(), data_pointer, offset)); |
| case BIGINT64_ELEMENTS: |
| return LoadFixedBigInt64ArrayElementAsTagged(data_pointer, offset); |
| case BIGUINT64_ELEMENTS: |
| return LoadFixedBigUint64ArrayElementAsTagged(data_pointer, offset); |
| default: |
| UNREACHABLE(); |
| } |
| } |
| |
| TNode<Numeric> CodeStubAssembler::LoadFixedTypedArrayElementAsTagged( |
| TNode<WordT> data_pointer, TNode<Smi> index, TNode<Int32T> elements_kind) { |
| TVARIABLE(Numeric, var_result); |
| Label done(this), if_unknown_type(this, Label::kDeferred); |
| int32_t elements_kinds[] = { |
| #define TYPED_ARRAY_CASE(Type, type, TYPE, ctype) TYPE##_ELEMENTS, |
| TYPED_ARRAYS(TYPED_ARRAY_CASE) |
| #undef TYPED_ARRAY_CASE |
| }; |
| |
| #define TYPED_ARRAY_CASE(Type, type, TYPE, ctype) Label if_##type##array(this); |
| TYPED_ARRAYS(TYPED_ARRAY_CASE) |
| #undef TYPED_ARRAY_CASE |
| |
| Label* elements_kind_labels[] = { |
| #define TYPED_ARRAY_CASE(Type, type, TYPE, ctype) &if_##type##array, |
| TYPED_ARRAYS(TYPED_ARRAY_CASE) |
| #undef TYPED_ARRAY_CASE |
| }; |
| STATIC_ASSERT(arraysize(elements_kinds) == arraysize(elements_kind_labels)); |
| |
| Switch(elements_kind, &if_unknown_type, elements_kinds, elements_kind_labels, |
| arraysize(elements_kinds)); |
| |
| BIND(&if_unknown_type); |
| Unreachable(); |
| |
| #define TYPED_ARRAY_CASE(Type, type, TYPE, ctype) \ |
| BIND(&if_##type##array); \ |
| { \ |
| var_result = CAST(LoadFixedTypedArrayElementAsTagged( \ |
| data_pointer, index, TYPE##_ELEMENTS, SMI_PARAMETERS)); \ |
| Goto(&done); \ |
| } |
| TYPED_ARRAYS(TYPED_ARRAY_CASE) |
| #undef TYPED_ARRAY_CASE |
| |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| void CodeStubAssembler::StoreFixedTypedArrayElementFromTagged( |
| TNode<Context> context, TNode<FixedTypedArrayBase> elements, |
| TNode<Object> index_node, TNode<Object> value, ElementsKind elements_kind, |
| ParameterMode parameter_mode) { |
| TNode<RawPtrT> data_pointer = LoadFixedTypedArrayBackingStore(elements); |
| switch (elements_kind) { |
| case UINT8_ELEMENTS: |
| case UINT8_CLAMPED_ELEMENTS: |
| case INT8_ELEMENTS: |
| case UINT16_ELEMENTS: |
| case INT16_ELEMENTS: |
| StoreElement(data_pointer, elements_kind, index_node, |
| SmiToInt32(CAST(value)), parameter_mode); |
| break; |
| case UINT32_ELEMENTS: |
| case INT32_ELEMENTS: |
| StoreElement(data_pointer, elements_kind, index_node, |
| TruncateTaggedToWord32(context, value), parameter_mode); |
| break; |
| case FLOAT32_ELEMENTS: |
| StoreElement(data_pointer, elements_kind, index_node, |
| TruncateFloat64ToFloat32(LoadHeapNumberValue(CAST(value))), |
| parameter_mode); |
| break; |
| case FLOAT64_ELEMENTS: |
| StoreElement(data_pointer, elements_kind, index_node, |
| LoadHeapNumberValue(CAST(value)), parameter_mode); |
| break; |
| case BIGUINT64_ELEMENTS: |
| case BIGINT64_ELEMENTS: { |
| TNode<IntPtrT> offset = |
| ElementOffsetFromIndex(index_node, elements_kind, parameter_mode, 0); |
| EmitBigTypedArrayElementStore(elements, data_pointer, offset, |
| CAST(value)); |
| break; |
| } |
| default: |
| UNREACHABLE(); |
| } |
| } |
| |
| TNode<MaybeObject> CodeStubAssembler::LoadFeedbackVectorSlot( |
| Node* object, Node* slot_index_node, int additional_offset, |
| ParameterMode parameter_mode) { |
| CSA_SLOW_ASSERT(this, IsFeedbackVector(object)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(slot_index_node, parameter_mode)); |
| int32_t header_size = |
| FeedbackVector::kFeedbackSlotsOffset + additional_offset - kHeapObjectTag; |
| Node* offset = ElementOffsetFromIndex(slot_index_node, HOLEY_ELEMENTS, |
| parameter_mode, header_size); |
| CSA_SLOW_ASSERT( |
| this, IsOffsetInBounds(offset, LoadFeedbackVectorLength(CAST(object)), |
| FeedbackVector::kHeaderSize)); |
| return UncheckedCast<MaybeObject>( |
| Load(MachineType::AnyTagged(), object, offset)); |
| } |
| |
| template <typename Array> |
| TNode<Int32T> CodeStubAssembler::LoadAndUntagToWord32ArrayElement( |
| TNode<Array> object, int array_header_size, Node* index_node, |
| int additional_offset, ParameterMode parameter_mode) { |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(index_node, parameter_mode)); |
| DCHECK(IsAligned(additional_offset, kTaggedSize)); |
| int endian_correction = 0; |
| #if V8_TARGET_LITTLE_ENDIAN |
| if (SmiValuesAre32Bits()) endian_correction = 4; |
| #endif |
| int32_t header_size = array_header_size + additional_offset - kHeapObjectTag + |
| endian_correction; |
| Node* offset = ElementOffsetFromIndex(index_node, HOLEY_ELEMENTS, |
| parameter_mode, header_size); |
| CSA_ASSERT(this, IsOffsetInBounds(offset, LoadArrayLength(object), |
| array_header_size + endian_correction)); |
| if (SmiValuesAre32Bits()) { |
| return UncheckedCast<Int32T>(Load(MachineType::Int32(), object, offset)); |
| } else { |
| return SmiToInt32(Load(MachineType::AnyTagged(), object, offset)); |
| } |
| } |
| |
| TNode<Int32T> CodeStubAssembler::LoadAndUntagToWord32FixedArrayElement( |
| TNode<FixedArray> object, Node* index_node, int additional_offset, |
| ParameterMode parameter_mode) { |
| CSA_SLOW_ASSERT(this, IsFixedArraySubclass(object)); |
| return LoadAndUntagToWord32ArrayElement(object, FixedArray::kHeaderSize, |
| index_node, additional_offset, |
| parameter_mode); |
| } |
| |
| TNode<MaybeObject> CodeStubAssembler::LoadWeakFixedArrayElement( |
| TNode<WeakFixedArray> object, Node* index, int additional_offset, |
| ParameterMode parameter_mode, LoadSensitivity needs_poisoning) { |
| return LoadArrayElement(object, WeakFixedArray::kHeaderSize, index, |
| additional_offset, parameter_mode, needs_poisoning); |
| } |
| |
| TNode<Float64T> CodeStubAssembler::LoadFixedDoubleArrayElement( |
| SloppyTNode<FixedDoubleArray> object, Node* index_node, |
| MachineType machine_type, int additional_offset, |
| ParameterMode parameter_mode, Label* if_hole) { |
| CSA_ASSERT(this, IsFixedDoubleArray(object)); |
| DCHECK(IsAligned(additional_offset, kTaggedSize)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(index_node, parameter_mode)); |
| int32_t header_size = |
| FixedDoubleArray::kHeaderSize + additional_offset - kHeapObjectTag; |
| TNode<IntPtrT> offset = ElementOffsetFromIndex( |
| index_node, HOLEY_DOUBLE_ELEMENTS, parameter_mode, header_size); |
| CSA_ASSERT(this, IsOffsetInBounds( |
| offset, LoadAndUntagFixedArrayBaseLength(object), |
| FixedDoubleArray::kHeaderSize, HOLEY_DOUBLE_ELEMENTS)); |
| return LoadDoubleWithHoleCheck(object, offset, if_hole, machine_type); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadFixedArrayBaseElementAsTagged( |
| TNode<FixedArrayBase> elements, TNode<IntPtrT> index, |
| TNode<Int32T> elements_kind, Label* if_accessor, Label* if_hole) { |
| TVARIABLE(Object, var_result); |
| Label done(this), if_packed(this), if_holey(this), if_packed_double(this), |
| if_holey_double(this), if_dictionary(this, Label::kDeferred); |
| |
| int32_t kinds[] = {// Handled by if_packed. |
| PACKED_SMI_ELEMENTS, PACKED_ELEMENTS, |
| // Handled by if_holey. |
| HOLEY_SMI_ELEMENTS, HOLEY_ELEMENTS, |
| // Handled by if_packed_double. |
| PACKED_DOUBLE_ELEMENTS, |
| // Handled by if_holey_double. |
| HOLEY_DOUBLE_ELEMENTS}; |
| Label* labels[] = {// PACKED_{SMI,}_ELEMENTS |
| &if_packed, &if_packed, |
| // HOLEY_{SMI,}_ELEMENTS |
| &if_holey, &if_holey, |
| // PACKED_DOUBLE_ELEMENTS |
| &if_packed_double, |
| // HOLEY_DOUBLE_ELEMENTS |
| &if_holey_double}; |
| Switch(elements_kind, &if_dictionary, kinds, labels, arraysize(kinds)); |
| |
| BIND(&if_packed); |
| { |
| var_result = LoadFixedArrayElement(CAST(elements), index, 0); |
| Goto(&done); |
| } |
| |
| BIND(&if_holey); |
| { |
| var_result = LoadFixedArrayElement(CAST(elements), index); |
| Branch(WordEqual(var_result.value(), TheHoleConstant()), if_hole, &done); |
| } |
| |
| BIND(&if_packed_double); |
| { |
| var_result = AllocateHeapNumberWithValue(LoadFixedDoubleArrayElement( |
| CAST(elements), index, MachineType::Float64())); |
| Goto(&done); |
| } |
| |
| BIND(&if_holey_double); |
| { |
| var_result = AllocateHeapNumberWithValue(LoadFixedDoubleArrayElement( |
| CAST(elements), index, MachineType::Float64(), 0, INTPTR_PARAMETERS, |
| if_hole)); |
| Goto(&done); |
| } |
| |
| BIND(&if_dictionary); |
| { |
| CSA_ASSERT(this, IsDictionaryElementsKind(elements_kind)); |
| var_result = BasicLoadNumberDictionaryElement(CAST(elements), index, |
| if_accessor, if_hole); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| TNode<Float64T> CodeStubAssembler::LoadDoubleWithHoleCheck( |
| SloppyTNode<Object> base, SloppyTNode<IntPtrT> offset, Label* if_hole, |
| MachineType machine_type) { |
| if (if_hole) { |
| // TODO(ishell): Compare only the upper part for the hole once the |
| // compiler is able to fold addition of already complex |offset| with |
| // |kIeeeDoubleExponentWordOffset| into one addressing mode. |
| if (Is64()) { |
| Node* element = Load(MachineType::Uint64(), base, offset); |
| GotoIf(Word64Equal(element, Int64Constant(kHoleNanInt64)), if_hole); |
| } else { |
| Node* element_upper = Load( |
| MachineType::Uint32(), base, |
| IntPtrAdd(offset, IntPtrConstant(kIeeeDoubleExponentWordOffset))); |
| GotoIf(Word32Equal(element_upper, Int32Constant(kHoleNanUpper32)), |
| if_hole); |
| } |
| } |
| if (machine_type.IsNone()) { |
| // This means the actual value is not needed. |
| return TNode<Float64T>(); |
| } |
| return UncheckedCast<Float64T>(Load(machine_type, base, offset)); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadContextElement( |
| SloppyTNode<Context> context, int slot_index) { |
| int offset = Context::SlotOffset(slot_index); |
| return UncheckedCast<Object>( |
| Load(MachineType::AnyTagged(), context, IntPtrConstant(offset))); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadContextElement( |
| SloppyTNode<Context> context, SloppyTNode<IntPtrT> slot_index) { |
| Node* offset = ElementOffsetFromIndex( |
| slot_index, PACKED_ELEMENTS, INTPTR_PARAMETERS, Context::SlotOffset(0)); |
| return UncheckedCast<Object>(Load(MachineType::AnyTagged(), context, offset)); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadContextElement(TNode<Context> context, |
| TNode<Smi> slot_index) { |
| Node* offset = ElementOffsetFromIndex(slot_index, PACKED_ELEMENTS, |
| SMI_PARAMETERS, Context::SlotOffset(0)); |
| return UncheckedCast<Object>(Load(MachineType::AnyTagged(), context, offset)); |
| } |
| |
| void CodeStubAssembler::StoreContextElement(SloppyTNode<Context> context, |
| int slot_index, |
| SloppyTNode<Object> value) { |
| int offset = Context::SlotOffset(slot_index); |
| Store(context, IntPtrConstant(offset), value); |
| } |
| |
| void CodeStubAssembler::StoreContextElement(SloppyTNode<Context> context, |
| SloppyTNode<IntPtrT> slot_index, |
| SloppyTNode<Object> value) { |
| Node* offset = IntPtrAdd(TimesTaggedSize(slot_index), |
| IntPtrConstant(Context::SlotOffset(0))); |
| Store(context, offset, value); |
| } |
| |
| void CodeStubAssembler::StoreContextElementNoWriteBarrier( |
| SloppyTNode<Context> context, int slot_index, SloppyTNode<Object> value) { |
| int offset = Context::SlotOffset(slot_index); |
| StoreNoWriteBarrier(MachineRepresentation::kTagged, context, |
| IntPtrConstant(offset), value); |
| } |
| |
| TNode<Context> CodeStubAssembler::LoadNativeContext( |
| SloppyTNode<Context> context) { |
| return UncheckedCast<Context>( |
| LoadContextElement(context, Context::NATIVE_CONTEXT_INDEX)); |
| } |
| |
| TNode<Context> CodeStubAssembler::LoadModuleContext( |
| SloppyTNode<Context> context) { |
| Node* module_map = LoadRoot(RootIndex::kModuleContextMap); |
| Variable cur_context(this, MachineRepresentation::kTaggedPointer); |
| cur_context.Bind(context); |
| |
| Label context_found(this); |
| |
| Variable* context_search_loop_variables[1] = {&cur_context}; |
| Label context_search(this, 1, context_search_loop_variables); |
| |
| // Loop until cur_context->map() is module_map. |
| Goto(&context_search); |
| BIND(&context_search); |
| { |
| CSA_ASSERT(this, Word32BinaryNot(IsNativeContext(cur_context.value()))); |
| GotoIf(WordEqual(LoadMap(cur_context.value()), module_map), &context_found); |
| |
| cur_context.Bind( |
| LoadContextElement(cur_context.value(), Context::PREVIOUS_INDEX)); |
| Goto(&context_search); |
| } |
| |
| BIND(&context_found); |
| return UncheckedCast<Context>(cur_context.value()); |
| } |
| |
| TNode<Map> CodeStubAssembler::LoadJSArrayElementsMap( |
| SloppyTNode<Int32T> kind, SloppyTNode<Context> native_context) { |
| CSA_ASSERT(this, IsFastElementsKind(kind)); |
| CSA_ASSERT(this, IsNativeContext(native_context)); |
| Node* offset = IntPtrAdd(IntPtrConstant(Context::FIRST_JS_ARRAY_MAP_SLOT), |
| ChangeInt32ToIntPtr(kind)); |
| return UncheckedCast<Map>(LoadContextElement(native_context, offset)); |
| } |
| |
| TNode<Map> CodeStubAssembler::LoadJSArrayElementsMap( |
| ElementsKind kind, SloppyTNode<Context> native_context) { |
| CSA_ASSERT(this, IsNativeContext(native_context)); |
| return UncheckedCast<Map>( |
| LoadContextElement(native_context, Context::ArrayMapIndex(kind))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsGeneratorFunction( |
| TNode<JSFunction> function) { |
| TNode<SharedFunctionInfo> const shared_function_info = |
| CAST(LoadObjectField(function, JSFunction::kSharedFunctionInfoOffset)); |
| |
| TNode<Uint32T> const function_kind = |
| DecodeWord32<SharedFunctionInfo::FunctionKindBits>(LoadObjectField( |
| shared_function_info, SharedFunctionInfo::kFlagsOffset, |
| MachineType::Uint32())); |
| |
| return TNode<BoolT>::UncheckedCast(Word32Or( |
| Word32Or( |
| Word32Or( |
| Word32Equal(function_kind, |
| Int32Constant(FunctionKind::kAsyncGeneratorFunction)), |
| Word32Equal( |
| function_kind, |
| Int32Constant(FunctionKind::kAsyncConciseGeneratorMethod))), |
| Word32Equal(function_kind, |
| Int32Constant(FunctionKind::kGeneratorFunction))), |
| Word32Equal(function_kind, |
| Int32Constant(FunctionKind::kConciseGeneratorMethod)))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::HasPrototypeProperty(TNode<JSFunction> function, |
| TNode<Map> map) { |
| // (has_prototype_slot() && IsConstructor()) || |
| // IsGeneratorFunction(shared()->kind()) |
| uint32_t mask = |
| Map::HasPrototypeSlotBit::kMask | Map::IsConstructorBit::kMask; |
| return TNode<BoolT>::UncheckedCast( |
| Word32Or(IsAllSetWord32(LoadMapBitField(map), mask), |
| IsGeneratorFunction(function))); |
| } |
| |
| void CodeStubAssembler::GotoIfPrototypeRequiresRuntimeLookup( |
| TNode<JSFunction> function, TNode<Map> map, Label* runtime) { |
| // !has_prototype_property() || has_non_instance_prototype() |
| GotoIfNot(HasPrototypeProperty(function, map), runtime); |
| GotoIf(IsSetWord32<Map::HasNonInstancePrototypeBit>(LoadMapBitField(map)), |
| runtime); |
| } |
| |
| Node* CodeStubAssembler::LoadJSFunctionPrototype(Node* function, |
| Label* if_bailout) { |
| CSA_ASSERT(this, TaggedIsNotSmi(function)); |
| CSA_ASSERT(this, IsJSFunction(function)); |
| CSA_ASSERT(this, IsFunctionWithPrototypeSlotMap(LoadMap(function))); |
| CSA_ASSERT(this, IsClearWord32<Map::HasNonInstancePrototypeBit>( |
| LoadMapBitField(LoadMap(function)))); |
| Node* proto_or_map = |
| LoadObjectField(function, JSFunction::kPrototypeOrInitialMapOffset); |
| GotoIf(IsTheHole(proto_or_map), if_bailout); |
| |
| VARIABLE(var_result, MachineRepresentation::kTagged, proto_or_map); |
| Label done(this, &var_result); |
| GotoIfNot(IsMap(proto_or_map), &done); |
| |
| var_result.Bind(LoadMapPrototype(proto_or_map)); |
| Goto(&done); |
| |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| TNode<BytecodeArray> CodeStubAssembler::LoadSharedFunctionInfoBytecodeArray( |
| SloppyTNode<SharedFunctionInfo> shared) { |
| Node* function_data = |
| LoadObjectField(shared, SharedFunctionInfo::kFunctionDataOffset); |
| |
| VARIABLE(var_result, MachineRepresentation::kTagged, function_data); |
| Label done(this, &var_result); |
| |
| GotoIfNot(HasInstanceType(function_data, INTERPRETER_DATA_TYPE), &done); |
| Node* bytecode_array = |
| LoadObjectField(function_data, InterpreterData::kBytecodeArrayOffset); |
| var_result.Bind(bytecode_array); |
| Goto(&done); |
| |
| BIND(&done); |
| return CAST(var_result.value()); |
| } |
| |
| void CodeStubAssembler::StoreObjectByteNoWriteBarrier(TNode<HeapObject> object, |
| int offset, |
| TNode<Word32T> value) { |
| StoreNoWriteBarrier(MachineRepresentation::kWord8, object, |
| IntPtrConstant(offset - kHeapObjectTag), value); |
| } |
| |
| void CodeStubAssembler::StoreHeapNumberValue(SloppyTNode<HeapNumber> object, |
| SloppyTNode<Float64T> value) { |
| StoreObjectFieldNoWriteBarrier(object, HeapNumber::kValueOffset, value, |
| MachineRepresentation::kFloat64); |
| } |
| |
| void CodeStubAssembler::StoreMutableHeapNumberValue( |
| SloppyTNode<MutableHeapNumber> object, SloppyTNode<Float64T> value) { |
| StoreObjectFieldNoWriteBarrier(object, MutableHeapNumber::kValueOffset, value, |
| MachineRepresentation::kFloat64); |
| } |
| |
| void CodeStubAssembler::StoreObjectField(Node* object, int offset, |
| Node* value) { |
| DCHECK_NE(HeapObject::kMapOffset, offset); // Use StoreMap instead. |
| |
| OptimizedStoreField(MachineRepresentation::kTagged, |
| UncheckedCast<HeapObject>(object), offset, value, |
| WriteBarrierKind::kFullWriteBarrier); |
| } |
| |
| void CodeStubAssembler::StoreObjectField(Node* object, Node* offset, |
| Node* value) { |
| int const_offset; |
| if (ToInt32Constant(offset, const_offset)) { |
| StoreObjectField(object, const_offset, value); |
| } else { |
| Store(object, IntPtrSub(offset, IntPtrConstant(kHeapObjectTag)), value); |
| } |
| } |
| |
| void CodeStubAssembler::StoreObjectFieldNoWriteBarrier( |
| Node* object, int offset, Node* value, MachineRepresentation rep) { |
| OptimizedStoreField(rep, UncheckedCast<HeapObject>(object), offset, value, |
| WriteBarrierKind::kNoWriteBarrier); |
| } |
| |
| void CodeStubAssembler::StoreObjectFieldNoWriteBarrier( |
| Node* object, Node* offset, Node* value, MachineRepresentation rep) { |
| int const_offset; |
| if (ToInt32Constant(offset, const_offset)) { |
| return StoreObjectFieldNoWriteBarrier(object, const_offset, value, rep); |
| } |
| StoreNoWriteBarrier(rep, object, |
| IntPtrSub(offset, IntPtrConstant(kHeapObjectTag)), value); |
| } |
| |
| void CodeStubAssembler::StoreMap(Node* object, Node* map) { |
| OptimizedStoreMap(UncheckedCast<HeapObject>(object), CAST(map)); |
| } |
| |
| void CodeStubAssembler::StoreMapNoWriteBarrier(Node* object, |
| RootIndex map_root_index) { |
| StoreMapNoWriteBarrier(object, LoadRoot(map_root_index)); |
| } |
| |
| void CodeStubAssembler::StoreMapNoWriteBarrier(Node* object, Node* map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| OptimizedStoreField(MachineRepresentation::kTaggedPointer, |
| UncheckedCast<HeapObject>(object), HeapObject::kMapOffset, |
| map, WriteBarrierKind::kNoWriteBarrier); |
| } |
| |
| void CodeStubAssembler::StoreObjectFieldRoot(Node* object, int offset, |
| RootIndex root_index) { |
| if (RootsTable::IsImmortalImmovable(root_index)) { |
| return StoreObjectFieldNoWriteBarrier(object, offset, LoadRoot(root_index)); |
| } else { |
| return StoreObjectField(object, offset, LoadRoot(root_index)); |
| } |
| } |
| |
| void CodeStubAssembler::StoreJSArrayLength(TNode<JSArray> array, |
| TNode<Smi> length) { |
| StoreObjectFieldNoWriteBarrier(array, JSArray::kLengthOffset, length); |
| } |
| |
| void CodeStubAssembler::StoreElements(TNode<Object> object, |
| TNode<FixedArrayBase> elements) { |
| StoreObjectField(object, JSObject::kElementsOffset, elements); |
| } |
| |
| void CodeStubAssembler::StoreFixedArrayOrPropertyArrayElement( |
| Node* object, Node* index_node, Node* value, WriteBarrierMode barrier_mode, |
| int additional_offset, ParameterMode parameter_mode) { |
| CSA_SLOW_ASSERT( |
| this, Word32Or(IsFixedArraySubclass(object), IsPropertyArray(object))); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(index_node, parameter_mode)); |
| DCHECK(barrier_mode == SKIP_WRITE_BARRIER || |
| barrier_mode == UPDATE_WRITE_BARRIER); |
| DCHECK(IsAligned(additional_offset, kTaggedSize)); |
| STATIC_ASSERT(static_cast<int>(FixedArray::kHeaderSize) == |
| static_cast<int>(PropertyArray::kHeaderSize)); |
| int header_size = |
| FixedArray::kHeaderSize + additional_offset - kHeapObjectTag; |
| Node* offset = ElementOffsetFromIndex(index_node, HOLEY_ELEMENTS, |
| parameter_mode, header_size); |
| STATIC_ASSERT(static_cast<int>(FixedArrayBase::kLengthOffset) == |
| static_cast<int>(WeakFixedArray::kLengthOffset)); |
| STATIC_ASSERT(static_cast<int>(FixedArrayBase::kLengthOffset) == |
| static_cast<int>(PropertyArray::kLengthAndHashOffset)); |
| // Check that index_node + additional_offset <= object.length. |
| // TODO(cbruni): Use proper LoadXXLength helpers |
| CSA_ASSERT( |
| this, |
| IsOffsetInBounds( |
| offset, |
| Select<IntPtrT>( |
| IsPropertyArray(object), |
| [=] { |
| TNode<IntPtrT> length_and_hash = LoadAndUntagObjectField( |
| object, PropertyArray::kLengthAndHashOffset); |
| return TNode<IntPtrT>::UncheckedCast( |
| DecodeWord<PropertyArray::LengthField>(length_and_hash)); |
| }, |
| [=] { |
| return LoadAndUntagObjectField(object, |
| FixedArrayBase::kLengthOffset); |
| }), |
| FixedArray::kHeaderSize)); |
| if (barrier_mode == SKIP_WRITE_BARRIER) { |
| StoreNoWriteBarrier(MachineRepresentation::kTagged, object, offset, value); |
| } else { |
| Store(object, offset, value); |
| } |
| } |
| |
| void CodeStubAssembler::StoreFixedDoubleArrayElement( |
| TNode<FixedDoubleArray> object, Node* index_node, TNode<Float64T> value, |
| ParameterMode parameter_mode, CheckBounds check_bounds) { |
| CSA_ASSERT(this, IsFixedDoubleArray(object)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(index_node, parameter_mode)); |
| if (NeedsBoundsCheck(check_bounds)) { |
| FixedArrayBoundsCheck(object, index_node, 0, parameter_mode); |
| } |
| Node* offset = |
| ElementOffsetFromIndex(index_node, PACKED_DOUBLE_ELEMENTS, parameter_mode, |
| FixedArray::kHeaderSize - kHeapObjectTag); |
| MachineRepresentation rep = MachineRepresentation::kFloat64; |
| StoreNoWriteBarrier(rep, object, offset, value); |
| } |
| |
| void CodeStubAssembler::StoreFeedbackVectorSlot(Node* object, |
| Node* slot_index_node, |
| Node* value, |
| WriteBarrierMode barrier_mode, |
| int additional_offset, |
| ParameterMode parameter_mode) { |
| CSA_SLOW_ASSERT(this, IsFeedbackVector(object)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(slot_index_node, parameter_mode)); |
| DCHECK(IsAligned(additional_offset, kTaggedSize)); |
| DCHECK(barrier_mode == SKIP_WRITE_BARRIER || |
| barrier_mode == UPDATE_WRITE_BARRIER); |
| int header_size = |
| FeedbackVector::kFeedbackSlotsOffset + additional_offset - kHeapObjectTag; |
| Node* offset = ElementOffsetFromIndex(slot_index_node, HOLEY_ELEMENTS, |
| parameter_mode, header_size); |
| // Check that slot_index_node <= object.length. |
| CSA_ASSERT(this, |
| IsOffsetInBounds(offset, LoadFeedbackVectorLength(CAST(object)), |
| FeedbackVector::kHeaderSize)); |
| if (barrier_mode == SKIP_WRITE_BARRIER) { |
| StoreNoWriteBarrier(MachineRepresentation::kTagged, object, offset, value); |
| } else { |
| Store(object, offset, value); |
| } |
| } |
| |
| void CodeStubAssembler::EnsureArrayLengthWritable(TNode<Map> map, |
| Label* bailout) { |
| // Don't support arrays in dictionary named property mode. |
| GotoIf(IsDictionaryMap(map), bailout); |
| |
| // Check whether the length property is writable. The length property is the |
| // only default named property on arrays. It's nonconfigurable, hence is |
| // guaranteed to stay the first property. |
| TNode<DescriptorArray> descriptors = LoadMapDescriptors(map); |
| |
| int length_index = JSArray::kLengthDescriptorIndex; |
| #ifdef DEBUG |
| TNode<Name> maybe_length = |
| LoadKeyByDescriptorEntry(descriptors, length_index); |
| CSA_ASSERT(this, |
| WordEqual(maybe_length, LoadRoot(RootIndex::klength_string))); |
| #endif |
| |
| TNode<Uint32T> details = |
| LoadDetailsByDescriptorEntry(descriptors, length_index); |
| GotoIf(IsSetWord32(details, PropertyDetails::kAttributesReadOnlyMask), |
| bailout); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::EnsureArrayPushable(TNode<Map> map, |
| Label* bailout) { |
| // Disallow pushing onto prototypes. It might be the JSArray prototype. |
| // Disallow pushing onto non-extensible objects. |
| Comment("Disallow pushing onto prototypes"); |
| Node* bit_field2 = LoadMapBitField2(map); |
| int mask = Map::IsPrototypeMapBit::kMask | Map::IsExtensibleBit::kMask; |
| Node* test = Word32And(bit_field2, Int32Constant(mask)); |
| GotoIf(Word32NotEqual(test, Int32Constant(Map::IsExtensibleBit::kMask)), |
| bailout); |
| |
| EnsureArrayLengthWritable(map, bailout); |
| |
| TNode<Uint32T> kind = DecodeWord32<Map::ElementsKindBits>(bit_field2); |
| return Signed(kind); |
| } |
| |
| void CodeStubAssembler::PossiblyGrowElementsCapacity( |
| ParameterMode mode, ElementsKind kind, Node* array, Node* length, |
| Variable* var_elements, Node* growth, Label* bailout) { |
| Label fits(this, var_elements); |
| Node* capacity = |
| TaggedToParameter(LoadFixedArrayBaseLength(var_elements->value()), mode); |
| // length and growth nodes are already in a ParameterMode appropriate |
| // representation. |
| Node* new_length = IntPtrOrSmiAdd(growth, length, mode); |
| GotoIfNot(IntPtrOrSmiGreaterThan(new_length, capacity, mode), &fits); |
| Node* new_capacity = CalculateNewElementsCapacity(new_length, mode); |
| var_elements->Bind(GrowElementsCapacity(array, var_elements->value(), kind, |
| kind, capacity, new_capacity, mode, |
| bailout)); |
| Goto(&fits); |
| BIND(&fits); |
| } |
| |
| TNode<Smi> CodeStubAssembler::BuildAppendJSArray(ElementsKind kind, |
| SloppyTNode<JSArray> array, |
| CodeStubArguments* args, |
| TVariable<IntPtrT>* arg_index, |
| Label* bailout) { |
| CSA_SLOW_ASSERT(this, IsJSArray(array)); |
| Comment("BuildAppendJSArray: ", ElementsKindToString(kind)); |
| Label pre_bailout(this); |
| Label success(this); |
| TVARIABLE(Smi, var_tagged_length); |
| ParameterMode mode = OptimalParameterMode(); |
| VARIABLE(var_length, OptimalParameterRepresentation(), |
| TaggedToParameter(LoadFastJSArrayLength(array), mode)); |
| VARIABLE(var_elements, MachineRepresentation::kTagged, LoadElements(array)); |
| |
| // Resize the capacity of the fixed array if it doesn't fit. |
| TNode<IntPtrT> first = arg_index->value(); |
| Node* growth = IntPtrToParameter( |
| IntPtrSub(UncheckedCast<IntPtrT>(args->GetLength(INTPTR_PARAMETERS)), |
| first), |
| mode); |
| PossiblyGrowElementsCapacity(mode, kind, array, var_length.value(), |
| &var_elements, growth, &pre_bailout); |
| |
| // Push each argument onto the end of the array now that there is enough |
| // capacity. |
| CodeStubAssembler::VariableList push_vars({&var_length}, zone()); |
| Node* elements = var_elements.value(); |
| args->ForEach( |
| push_vars, |
| [this, kind, mode, elements, &var_length, &pre_bailout](Node* arg) { |
| TryStoreArrayElement(kind, mode, &pre_bailout, elements, |
| var_length.value(), arg); |
| Increment(&var_length, 1, mode); |
| }, |
| first, nullptr); |
| { |
| TNode<Smi> length = ParameterToTagged(var_length.value(), mode); |
| var_tagged_length = length; |
| StoreObjectFieldNoWriteBarrier(array, JSArray::kLengthOffset, length); |
| Goto(&success); |
| } |
| |
| BIND(&pre_bailout); |
| { |
| TNode<Smi> length = ParameterToTagged(var_length.value(), mode); |
| var_tagged_length = length; |
| Node* diff = SmiSub(length, LoadFastJSArrayLength(array)); |
| StoreObjectFieldNoWriteBarrier(array, JSArray::kLengthOffset, length); |
| *arg_index = IntPtrAdd(arg_index->value(), SmiUntag(diff)); |
| Goto(bailout); |
| } |
| |
| BIND(&success); |
| return var_tagged_length.value(); |
| } |
| |
| void CodeStubAssembler::TryStoreArrayElement(ElementsKind kind, |
| ParameterMode mode, Label* bailout, |
| Node* elements, Node* index, |
| Node* value) { |
| if (IsSmiElementsKind(kind)) { |
| GotoIf(TaggedIsNotSmi(value), bailout); |
| } else if (IsDoubleElementsKind(kind)) { |
| GotoIfNotNumber(value, bailout); |
| } |
| if (IsDoubleElementsKind(kind)) value = ChangeNumberToFloat64(value); |
| StoreElement(elements, kind, index, value, mode); |
| } |
| |
| void CodeStubAssembler::BuildAppendJSArray(ElementsKind kind, Node* array, |
| Node* value, Label* bailout) { |
| CSA_SLOW_ASSERT(this, IsJSArray(array)); |
| Comment("BuildAppendJSArray: ", ElementsKindToString(kind)); |
| ParameterMode mode = OptimalParameterMode(); |
| VARIABLE(var_length, OptimalParameterRepresentation(), |
| TaggedToParameter(LoadFastJSArrayLength(array), mode)); |
| VARIABLE(var_elements, MachineRepresentation::kTagged, LoadElements(array)); |
| |
| // Resize the capacity of the fixed array if it doesn't fit. |
| Node* growth = IntPtrOrSmiConstant(1, mode); |
| PossiblyGrowElementsCapacity(mode, kind, array, var_length.value(), |
| &var_elements, growth, bailout); |
| |
| // Push each argument onto the end of the array now that there is enough |
| // capacity. |
| TryStoreArrayElement(kind, mode, bailout, var_elements.value(), |
| var_length.value(), value); |
| Increment(&var_length, 1, mode); |
| |
| Node* length = ParameterToTagged(var_length.value(), mode); |
| StoreObjectFieldNoWriteBarrier(array, JSArray::kLengthOffset, length); |
| } |
| |
| Node* CodeStubAssembler::AllocateCellWithValue(Node* value, |
| WriteBarrierMode mode) { |
| Node* result = Allocate(Cell::kSize, kNone); |
| StoreMapNoWriteBarrier(result, RootIndex::kCellMap); |
| StoreCellValue(result, value, mode); |
| return result; |
| } |
| |
| Node* CodeStubAssembler::LoadCellValue(Node* cell) { |
| CSA_SLOW_ASSERT(this, HasInstanceType(cell, CELL_TYPE)); |
| return LoadObjectField(cell, Cell::kValueOffset); |
| } |
| |
| void CodeStubAssembler::StoreCellValue(Node* cell, Node* value, |
| WriteBarrierMode mode) { |
| CSA_SLOW_ASSERT(this, HasInstanceType(cell, CELL_TYPE)); |
| DCHECK(mode == SKIP_WRITE_BARRIER || mode == UPDATE_WRITE_BARRIER); |
| |
| if (mode == UPDATE_WRITE_BARRIER) { |
| StoreObjectField(cell, Cell::kValueOffset, value); |
| } else { |
| StoreObjectFieldNoWriteBarrier(cell, Cell::kValueOffset, value); |
| } |
| } |
| |
| TNode<HeapNumber> CodeStubAssembler::AllocateHeapNumber() { |
| Node* result = Allocate(HeapNumber::kSize, kNone); |
| RootIndex heap_map_index = RootIndex::kHeapNumberMap; |
| StoreMapNoWriteBarrier(result, heap_map_index); |
| return UncheckedCast<HeapNumber>(result); |
| } |
| |
| TNode<HeapNumber> CodeStubAssembler::AllocateHeapNumberWithValue( |
| SloppyTNode<Float64T> value) { |
| TNode<HeapNumber> result = AllocateHeapNumber(); |
| StoreHeapNumberValue(result, value); |
| return result; |
| } |
| |
| TNode<MutableHeapNumber> CodeStubAssembler::AllocateMutableHeapNumber() { |
| Node* result = Allocate(MutableHeapNumber::kSize, kNone); |
| RootIndex heap_map_index = RootIndex::kMutableHeapNumberMap; |
| StoreMapNoWriteBarrier(result, heap_map_index); |
| return UncheckedCast<MutableHeapNumber>(result); |
| } |
| |
| TNode<Object> CodeStubAssembler::CloneIfMutablePrimitive(TNode<Object> object) { |
| TVARIABLE(Object, result, object); |
| Label done(this); |
| |
| GotoIf(TaggedIsSmi(object), &done); |
| GotoIfNot(IsMutableHeapNumber(UncheckedCast<HeapObject>(object)), &done); |
| { |
| // Mutable heap number found --- allocate a clone. |
| TNode<Float64T> value = |
| LoadHeapNumberValue(UncheckedCast<HeapNumber>(object)); |
| result = AllocateMutableHeapNumberWithValue(value); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<MutableHeapNumber> CodeStubAssembler::AllocateMutableHeapNumberWithValue( |
| SloppyTNode<Float64T> value) { |
| TNode<MutableHeapNumber> result = AllocateMutableHeapNumber(); |
| StoreMutableHeapNumberValue(result, value); |
| return result; |
| } |
| |
| TNode<BigInt> CodeStubAssembler::AllocateBigInt(TNode<IntPtrT> length) { |
| TNode<BigInt> result = AllocateRawBigInt(length); |
| StoreBigIntBitfield(result, |
| Word32Shl(TruncateIntPtrToInt32(length), |
| Int32Constant(BigInt::LengthBits::kShift))); |
| return result; |
| } |
| |
| TNode<BigInt> CodeStubAssembler::AllocateRawBigInt(TNode<IntPtrT> length) { |
| // This is currently used only for 64-bit wide BigInts. If more general |
| // applicability is required, a large-object check must be added. |
| CSA_ASSERT(this, UintPtrLessThan(length, IntPtrConstant(3))); |
| |
| TNode<IntPtrT> size = |
| IntPtrAdd(IntPtrConstant(BigInt::kHeaderSize), |
| Signed(WordShl(length, kSystemPointerSizeLog2))); |
| Node* raw_result = Allocate(size, kNone); |
| StoreMapNoWriteBarrier(raw_result, RootIndex::kBigIntMap); |
| if (FIELD_SIZE(BigInt::kOptionalPaddingOffset) != 0) { |
| DCHECK_EQ(4, FIELD_SIZE(BigInt::kOptionalPaddingOffset)); |
| StoreObjectFieldNoWriteBarrier(raw_result, BigInt::kOptionalPaddingOffset, |
| Int32Constant(0), |
| MachineRepresentation::kWord32); |
| } |
| return UncheckedCast<BigInt>(raw_result); |
| } |
| |
| void CodeStubAssembler::StoreBigIntBitfield(TNode<BigInt> bigint, |
| TNode<Word32T> bitfield) { |
| StoreObjectFieldNoWriteBarrier(bigint, BigInt::kBitfieldOffset, bitfield, |
| MachineRepresentation::kWord32); |
| } |
| |
| void CodeStubAssembler::StoreBigIntDigit(TNode<BigInt> bigint, int digit_index, |
| TNode<UintPtrT> digit) { |
| StoreObjectFieldNoWriteBarrier( |
| bigint, BigInt::kDigitsOffset + digit_index * kSystemPointerSize, digit, |
| UintPtrT::kMachineRepresentation); |
| } |
| |
| TNode<Word32T> CodeStubAssembler::LoadBigIntBitfield(TNode<BigInt> bigint) { |
| return UncheckedCast<Word32T>( |
| LoadObjectField(bigint, BigInt::kBitfieldOffset, MachineType::Uint32())); |
| } |
| |
| TNode<UintPtrT> CodeStubAssembler::LoadBigIntDigit(TNode<BigInt> bigint, |
| int digit_index) { |
| return UncheckedCast<UintPtrT>(LoadObjectField( |
| bigint, BigInt::kDigitsOffset + digit_index * kSystemPointerSize, |
| MachineType::UintPtr())); |
| } |
| |
| TNode<String> CodeStubAssembler::AllocateSeqOneByteString( |
| uint32_t length, AllocationFlags flags) { |
| Comment("AllocateSeqOneByteString"); |
| if (length == 0) { |
| return CAST(LoadRoot(RootIndex::kempty_string)); |
| } |
| Node* result = Allocate(SeqOneByteString::SizeFor(length), flags); |
| DCHECK(RootsTable::IsImmortalImmovable(RootIndex::kOneByteStringMap)); |
| StoreMapNoWriteBarrier(result, RootIndex::kOneByteStringMap); |
| StoreObjectFieldNoWriteBarrier(result, SeqOneByteString::kLengthOffset, |
| Uint32Constant(length), |
| MachineRepresentation::kWord32); |
| StoreObjectFieldNoWriteBarrier(result, SeqOneByteString::kHashFieldOffset, |
| Int32Constant(String::kEmptyHashField), |
| MachineRepresentation::kWord32); |
| return CAST(result); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsZeroOrContext(SloppyTNode<Object> object) { |
| return Select<BoolT>(WordEqual(object, SmiConstant(0)), |
| [=] { return Int32TrueConstant(); }, |
| [=] { return IsContext(CAST(object)); }); |
| } |
| |
| TNode<String> CodeStubAssembler::AllocateSeqOneByteString( |
| Node* context, TNode<Uint32T> length, AllocationFlags flags) { |
| Comment("AllocateSeqOneByteString"); |
| CSA_SLOW_ASSERT(this, IsZeroOrContext(context)); |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| |
| // Compute the SeqOneByteString size and check if it fits into new space. |
| Label if_lengthiszero(this), if_sizeissmall(this), |
| if_notsizeissmall(this, Label::kDeferred), if_join(this); |
| GotoIf(Word32Equal(length, Uint32Constant(0)), &if_lengthiszero); |
| |
| Node* raw_size = GetArrayAllocationSize( |
| Signed(ChangeUint32ToWord(length)), UINT8_ELEMENTS, INTPTR_PARAMETERS, |
| SeqOneByteString::kHeaderSize + kObjectAlignmentMask); |
| TNode<WordT> size = WordAnd(raw_size, IntPtrConstant(~kObjectAlignmentMask)); |
| Branch(IntPtrLessThanOrEqual(size, IntPtrConstant(kMaxRegularHeapObjectSize)), |
| &if_sizeissmall, &if_notsizeissmall); |
| |
| BIND(&if_sizeissmall); |
| { |
| // Just allocate the SeqOneByteString in new space. |
| TNode<Object> result = |
| AllocateInNewSpace(UncheckedCast<IntPtrT>(size), flags); |
| DCHECK(RootsTable::IsImmortalImmovable(RootIndex::kOneByteStringMap)); |
| StoreMapNoWriteBarrier(result, RootIndex::kOneByteStringMap); |
| StoreObjectFieldNoWriteBarrier(result, SeqOneByteString::kLengthOffset, |
| length, MachineRepresentation::kWord32); |
| StoreObjectFieldNoWriteBarrier(result, SeqOneByteString::kHashFieldOffset, |
| Int32Constant(String::kEmptyHashField), |
| MachineRepresentation::kWord32); |
| var_result.Bind(result); |
| Goto(&if_join); |
| } |
| |
| BIND(&if_notsizeissmall); |
| { |
| // We might need to allocate in large object space, go to the runtime. |
| Node* result = CallRuntime(Runtime::kAllocateSeqOneByteString, context, |
| ChangeUint32ToTagged(length)); |
| var_result.Bind(result); |
| Goto(&if_join); |
| } |
| |
| BIND(&if_lengthiszero); |
| { |
| var_result.Bind(LoadRoot(RootIndex::kempty_string)); |
| Goto(&if_join); |
| } |
| |
| BIND(&if_join); |
| return CAST(var_result.value()); |
| } |
| |
| TNode<String> CodeStubAssembler::AllocateSeqTwoByteString( |
| uint32_t length, AllocationFlags flags) { |
| Comment("AllocateSeqTwoByteString"); |
| if (length == 0) { |
| return CAST(LoadRoot(RootIndex::kempty_string)); |
| } |
| Node* result = Allocate(SeqTwoByteString::SizeFor(length), flags); |
| DCHECK(RootsTable::IsImmortalImmovable(RootIndex::kStringMap)); |
| StoreMapNoWriteBarrier(result, RootIndex::kStringMap); |
| StoreObjectFieldNoWriteBarrier(result, SeqTwoByteString::kLengthOffset, |
| Uint32Constant(length), |
| MachineRepresentation::kWord32); |
| StoreObjectFieldNoWriteBarrier(result, SeqTwoByteString::kHashFieldOffset, |
| Int32Constant(String::kEmptyHashField), |
| MachineRepresentation::kWord32); |
| return CAST(result); |
| } |
| |
| TNode<String> CodeStubAssembler::AllocateSeqTwoByteString( |
| Node* context, TNode<Uint32T> length, AllocationFlags flags) { |
| CSA_SLOW_ASSERT(this, IsZeroOrContext(context)); |
| Comment("AllocateSeqTwoByteString"); |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| |
| // Compute the SeqTwoByteString size and check if it fits into new space. |
| Label if_lengthiszero(this), if_sizeissmall(this), |
| if_notsizeissmall(this, Label::kDeferred), if_join(this); |
| GotoIf(Word32Equal(length, Uint32Constant(0)), &if_lengthiszero); |
| |
| Node* raw_size = GetArrayAllocationSize( |
| Signed(ChangeUint32ToWord(length)), UINT16_ELEMENTS, INTPTR_PARAMETERS, |
| SeqOneByteString::kHeaderSize + kObjectAlignmentMask); |
| TNode<WordT> size = WordAnd(raw_size, IntPtrConstant(~kObjectAlignmentMask)); |
| Branch(IntPtrLessThanOrEqual(size, IntPtrConstant(kMaxRegularHeapObjectSize)), |
| &if_sizeissmall, &if_notsizeissmall); |
| |
| BIND(&if_sizeissmall); |
| { |
| // Just allocate the SeqTwoByteString in new space. |
| TNode<Object> result = |
| AllocateInNewSpace(UncheckedCast<IntPtrT>(size), flags); |
| DCHECK(RootsTable::IsImmortalImmovable(RootIndex::kStringMap)); |
| StoreMapNoWriteBarrier(result, RootIndex::kStringMap); |
| StoreObjectFieldNoWriteBarrier(result, SeqTwoByteString::kLengthOffset, |
| length, MachineRepresentation::kWord32); |
| StoreObjectFieldNoWriteBarrier(result, SeqTwoByteString::kHashFieldOffset, |
| Int32Constant(String::kEmptyHashField), |
| MachineRepresentation::kWord32); |
| var_result.Bind(result); |
| Goto(&if_join); |
| } |
| |
| BIND(&if_notsizeissmall); |
| { |
| // We might need to allocate in large object space, go to the runtime. |
| Node* result = CallRuntime(Runtime::kAllocateSeqTwoByteString, context, |
| ChangeUint32ToTagged(length)); |
| var_result.Bind(result); |
| Goto(&if_join); |
| } |
| |
| BIND(&if_lengthiszero); |
| { |
| var_result.Bind(LoadRoot(RootIndex::kempty_string)); |
| Goto(&if_join); |
| } |
| |
| BIND(&if_join); |
| return CAST(var_result.value()); |
| } |
| |
| TNode<String> CodeStubAssembler::AllocateSlicedString(RootIndex map_root_index, |
| TNode<Uint32T> length, |
| TNode<String> parent, |
| TNode<Smi> offset) { |
| DCHECK(map_root_index == RootIndex::kSlicedOneByteStringMap || |
| map_root_index == RootIndex::kSlicedStringMap); |
| Node* result = Allocate(SlicedString::kSize); |
| DCHECK(RootsTable::IsImmortalImmovable(map_root_index)); |
| StoreMapNoWriteBarrier(result, map_root_index); |
| StoreObjectFieldNoWriteBarrier(result, SlicedString::kHashFieldOffset, |
| Int32Constant(String::kEmptyHashField), |
| MachineRepresentation::kWord32); |
| StoreObjectFieldNoWriteBarrier(result, SlicedString::kLengthOffset, length, |
| MachineRepresentation::kWord32); |
| StoreObjectFieldNoWriteBarrier(result, SlicedString::kParentOffset, parent, |
| MachineRepresentation::kTagged); |
| StoreObjectFieldNoWriteBarrier(result, SlicedString::kOffsetOffset, offset, |
| MachineRepresentation::kTagged); |
| return CAST(result); |
| } |
| |
| TNode<String> CodeStubAssembler::AllocateSlicedOneByteString( |
| TNode<Uint32T> length, TNode<String> parent, TNode<Smi> offset) { |
| return AllocateSlicedString(RootIndex::kSlicedOneByteStringMap, length, |
| parent, offset); |
| } |
| |
| TNode<String> CodeStubAssembler::AllocateSlicedTwoByteString( |
| TNode<Uint32T> length, TNode<String> parent, TNode<Smi> offset) { |
| return AllocateSlicedString(RootIndex::kSlicedStringMap, length, parent, |
| offset); |
| } |
| |
| TNode<String> CodeStubAssembler::AllocateConsString(TNode<Uint32T> length, |
| TNode<String> left, |
| TNode<String> right) { |
| // Added string can be a cons string. |
| Comment("Allocating ConsString"); |
| Node* left_instance_type = LoadInstanceType(left); |
| Node* right_instance_type = LoadInstanceType(right); |
| |
| // Determine the resulting ConsString map to use depending on whether |
| // any of {left} or {right} has two byte encoding. |
| STATIC_ASSERT(kOneByteStringTag != 0); |
| STATIC_ASSERT(kTwoByteStringTag == 0); |
| Node* combined_instance_type = |
| Word32And(left_instance_type, right_instance_type); |
| TNode<Map> result_map = CAST(Select<Object>( |
| IsSetWord32(combined_instance_type, kStringEncodingMask), |
| [=] { return LoadRoot(RootIndex::kConsOneByteStringMap); }, |
| [=] { return LoadRoot(RootIndex::kConsStringMap); })); |
| Node* result = AllocateInNewSpace(ConsString::kSize); |
| StoreMapNoWriteBarrier(result, result_map); |
| StoreObjectFieldNoWriteBarrier(result, ConsString::kLengthOffset, length, |
| MachineRepresentation::kWord32); |
| StoreObjectFieldNoWriteBarrier(result, ConsString::kHashFieldOffset, |
| Int32Constant(String::kEmptyHashField), |
| MachineRepresentation::kWord32); |
| StoreObjectFieldNoWriteBarrier(result, ConsString::kFirstOffset, left); |
| StoreObjectFieldNoWriteBarrier(result, ConsString::kSecondOffset, right); |
| return CAST(result); |
| } |
| |
| TNode<NameDictionary> CodeStubAssembler::AllocateNameDictionary( |
| int at_least_space_for) { |
| return AllocateNameDictionary(IntPtrConstant(at_least_space_for)); |
| } |
| |
| TNode<NameDictionary> CodeStubAssembler::AllocateNameDictionary( |
| TNode<IntPtrT> at_least_space_for) { |
| CSA_ASSERT(this, UintPtrLessThanOrEqual( |
| at_least_space_for, |
| IntPtrConstant(NameDictionary::kMaxCapacity))); |
| TNode<IntPtrT> capacity = HashTableComputeCapacity(at_least_space_for); |
| return AllocateNameDictionaryWithCapacity(capacity); |
| } |
| |
| TNode<NameDictionary> CodeStubAssembler::AllocateNameDictionaryWithCapacity( |
| TNode<IntPtrT> capacity) { |
| CSA_ASSERT(this, WordIsPowerOfTwo(capacity)); |
| CSA_ASSERT(this, IntPtrGreaterThan(capacity, IntPtrConstant(0))); |
| TNode<IntPtrT> length = EntryToIndex<NameDictionary>(capacity); |
| TNode<IntPtrT> store_size = IntPtrAdd( |
| TimesTaggedSize(length), IntPtrConstant(NameDictionary::kHeaderSize)); |
| |
| TNode<NameDictionary> result = |
| UncheckedCast<NameDictionary>(AllocateInNewSpace(store_size)); |
| Comment("Initialize NameDictionary"); |
| // Initialize FixedArray fields. |
| DCHECK(RootsTable::IsImmortalImmovable(RootIndex::kNameDictionaryMap)); |
| StoreMapNoWriteBarrier(result, RootIndex::kNameDictionaryMap); |
| StoreObjectFieldNoWriteBarrier(result, FixedArray::kLengthOffset, |
| SmiFromIntPtr(length)); |
| // Initialized HashTable fields. |
| TNode<Smi> zero = SmiConstant(0); |
| StoreFixedArrayElement(result, NameDictionary::kNumberOfElementsIndex, zero, |
| SKIP_WRITE_BARRIER); |
| StoreFixedArrayElement(result, NameDictionary::kNumberOfDeletedElementsIndex, |
| zero, SKIP_WRITE_BARRIER); |
| StoreFixedArrayElement(result, NameDictionary::kCapacityIndex, |
| SmiTag(capacity), SKIP_WRITE_BARRIER); |
| // Initialize Dictionary fields. |
| TNode<HeapObject> filler = UndefinedConstant(); |
| StoreFixedArrayElement(result, NameDictionary::kNextEnumerationIndexIndex, |
| SmiConstant(PropertyDetails::kInitialIndex), |
| SKIP_WRITE_BARRIER); |
| StoreFixedArrayElement(result, NameDictionary::kObjectHashIndex, |
| SmiConstant(PropertyArray::kNoHashSentinel), |
| SKIP_WRITE_BARRIER); |
| |
| // Initialize NameDictionary elements. |
| TNode<WordT> result_word = BitcastTaggedToWord(result); |
| TNode<WordT> start_address = IntPtrAdd( |
| result_word, IntPtrConstant(NameDictionary::OffsetOfElementAt( |
| NameDictionary::kElementsStartIndex) - |
| kHeapObjectTag)); |
| TNode<WordT> end_address = IntPtrAdd( |
| result_word, IntPtrSub(store_size, IntPtrConstant(kHeapObjectTag))); |
| StoreFieldsNoWriteBarrier(start_address, end_address, filler); |
| return result; |
| } |
| |
| TNode<NameDictionary> CodeStubAssembler::CopyNameDictionary( |
| TNode<NameDictionary> dictionary, Label* large_object_fallback) { |
| Comment("Copy boilerplate property dict"); |
| TNode<IntPtrT> capacity = SmiUntag(GetCapacity<NameDictionary>(dictionary)); |
| CSA_ASSERT(this, IntPtrGreaterThanOrEqual(capacity, IntPtrConstant(0))); |
| GotoIf(UintPtrGreaterThan( |
| capacity, IntPtrConstant(NameDictionary::kMaxRegularCapacity)), |
| large_object_fallback); |
| TNode<NameDictionary> properties = |
| AllocateNameDictionaryWithCapacity(capacity); |
| TNode<IntPtrT> length = SmiUntag(LoadFixedArrayBaseLength(dictionary)); |
| CopyFixedArrayElements(PACKED_ELEMENTS, dictionary, properties, length, |
| SKIP_WRITE_BARRIER, INTPTR_PARAMETERS); |
| return properties; |
| } |
| |
| template <typename CollectionType> |
| Node* CodeStubAssembler::AllocateOrderedHashTable() { |
| static const int kCapacity = CollectionType::kMinCapacity; |
| static const int kBucketCount = kCapacity / CollectionType::kLoadFactor; |
| static const int kDataTableLength = kCapacity * CollectionType::kEntrySize; |
| static const int kFixedArrayLength = |
| CollectionType::HashTableStartIndex() + kBucketCount + kDataTableLength; |
| static const int kDataTableStartIndex = |
| CollectionType::HashTableStartIndex() + kBucketCount; |
| |
| STATIC_ASSERT(base::bits::IsPowerOfTwo(kCapacity)); |
| STATIC_ASSERT(kCapacity <= CollectionType::MaxCapacity()); |
| |
| // Allocate the table and add the proper map. |
| const ElementsKind elements_kind = HOLEY_ELEMENTS; |
| TNode<IntPtrT> length_intptr = IntPtrConstant(kFixedArrayLength); |
| TNode<Map> fixed_array_map = |
| CAST(LoadRoot(CollectionType::GetMapRootIndex())); |
| TNode<FixedArray> table = |
| CAST(AllocateFixedArray(elements_kind, length_intptr, |
| kAllowLargeObjectAllocation, fixed_array_map)); |
| |
| // Initialize the OrderedHashTable fields. |
| const WriteBarrierMode barrier_mode = SKIP_WRITE_BARRIER; |
| StoreFixedArrayElement(table, CollectionType::NumberOfElementsIndex(), |
| SmiConstant(0), barrier_mode); |
| StoreFixedArrayElement(table, CollectionType::NumberOfDeletedElementsIndex(), |
| SmiConstant(0), barrier_mode); |
| StoreFixedArrayElement(table, CollectionType::NumberOfBucketsIndex(), |
| SmiConstant(kBucketCount), barrier_mode); |
| |
| // Fill the buckets with kNotFound. |
| TNode<Smi> not_found = SmiConstant(CollectionType::kNotFound); |
| STATIC_ASSERT(CollectionType::HashTableStartIndex() == |
| CollectionType::NumberOfBucketsIndex() + 1); |
| STATIC_ASSERT((CollectionType::HashTableStartIndex() + kBucketCount) == |
| kDataTableStartIndex); |
| for (int i = 0; i < kBucketCount; i++) { |
| StoreFixedArrayElement(table, CollectionType::HashTableStartIndex() + i, |
| not_found, barrier_mode); |
| } |
| |
| // Fill the data table with undefined. |
| STATIC_ASSERT(kDataTableStartIndex + kDataTableLength == kFixedArrayLength); |
| for (int i = 0; i < kDataTableLength; i++) { |
| StoreFixedArrayElement(table, kDataTableStartIndex + i, UndefinedConstant(), |
| barrier_mode); |
| } |
| |
| return table; |
| } |
| |
| template Node* CodeStubAssembler::AllocateOrderedHashTable<OrderedHashMap>(); |
| template Node* CodeStubAssembler::AllocateOrderedHashTable<OrderedHashSet>(); |
| |
| template <typename CollectionType> |
| TNode<CollectionType> CodeStubAssembler::AllocateSmallOrderedHashTable( |
| TNode<IntPtrT> capacity) { |
| CSA_ASSERT(this, WordIsPowerOfTwo(capacity)); |
| CSA_ASSERT(this, IntPtrLessThan( |
| capacity, IntPtrConstant(CollectionType::kMaxCapacity))); |
| |
| TNode<IntPtrT> data_table_start_offset = |
| IntPtrConstant(CollectionType::DataTableStartOffset()); |
| |
| TNode<IntPtrT> data_table_size = IntPtrMul( |
| capacity, IntPtrConstant(CollectionType::kEntrySize * kTaggedSize)); |
| |
| TNode<Int32T> hash_table_size = |
| Int32Div(TruncateIntPtrToInt32(capacity), |
| Int32Constant(CollectionType::kLoadFactor)); |
| |
| TNode<IntPtrT> hash_table_start_offset = |
| IntPtrAdd(data_table_start_offset, data_table_size); |
| |
| TNode<IntPtrT> hash_table_and_chain_table_size = |
| IntPtrAdd(ChangeInt32ToIntPtr(hash_table_size), capacity); |
| |
| TNode<IntPtrT> total_size = |
| IntPtrAdd(hash_table_start_offset, hash_table_and_chain_table_size); |
| |
| TNode<IntPtrT> total_size_word_aligned = |
| IntPtrAdd(total_size, IntPtrConstant(kTaggedSize - 1)); |
| total_size_word_aligned = ChangeInt32ToIntPtr( |
| Int32Div(TruncateIntPtrToInt32(total_size_word_aligned), |
| Int32Constant(kTaggedSize))); |
| total_size_word_aligned = |
| UncheckedCast<IntPtrT>(TimesTaggedSize(total_size_word_aligned)); |
| |
| // Allocate the table and add the proper map. |
| TNode<Map> small_ordered_hash_map = |
| CAST(LoadRoot(CollectionType::GetMapRootIndex())); |
| TNode<Object> table_obj = AllocateInNewSpace(total_size_word_aligned); |
| StoreMapNoWriteBarrier(table_obj, small_ordered_hash_map); |
| TNode<CollectionType> table = UncheckedCast<CollectionType>(table_obj); |
| |
| // Initialize the SmallOrderedHashTable fields. |
| StoreObjectByteNoWriteBarrier( |
| table, CollectionType::NumberOfBucketsOffset(), |
| Word32And(Int32Constant(0xFF), hash_table_size)); |
| StoreObjectByteNoWriteBarrier(table, CollectionType::NumberOfElementsOffset(), |
| Int32Constant(0)); |
| StoreObjectByteNoWriteBarrier( |
| table, CollectionType::NumberOfDeletedElementsOffset(), Int32Constant(0)); |
| |
| TNode<IntPtrT> table_address = |
| IntPtrSub(BitcastTaggedToWord(table), IntPtrConstant(kHeapObjectTag)); |
| TNode<IntPtrT> hash_table_start_address = |
| IntPtrAdd(table_address, hash_table_start_offset); |
| |
| // Initialize the HashTable part. |
| Node* memset = ExternalConstant(ExternalReference::libc_memset_function()); |
| CallCFunction3(MachineType::AnyTagged(), MachineType::Pointer(), |
| MachineType::IntPtr(), MachineType::UintPtr(), memset, |
| hash_table_start_address, IntPtrConstant(0xFF), |
| hash_table_and_chain_table_size); |
| |
| // Initialize the DataTable part. |
| TNode<HeapObject> filler = TheHoleConstant(); |
| TNode<WordT> data_table_start_address = |
| IntPtrAdd(table_address, data_table_start_offset); |
| TNode<WordT> data_table_end_address = |
| IntPtrAdd(data_table_start_address, data_table_size); |
| StoreFieldsNoWriteBarrier(data_table_start_address, data_table_end_address, |
| filler); |
| |
| return table; |
| } |
| |
| template TNode<SmallOrderedHashMap> |
| CodeStubAssembler::AllocateSmallOrderedHashTable<SmallOrderedHashMap>( |
| TNode<IntPtrT> capacity); |
| template TNode<SmallOrderedHashSet> |
| CodeStubAssembler::AllocateSmallOrderedHashTable<SmallOrderedHashSet>( |
| TNode<IntPtrT> capacity); |
| |
| template <typename CollectionType> |
| void CodeStubAssembler::FindOrderedHashTableEntry( |
| Node* table, Node* hash, |
| const std::function<void(Node*, Label*, Label*)>& key_compare, |
| Variable* entry_start_position, Label* entry_found, Label* not_found) { |
| // Get the index of the bucket. |
| Node* const number_of_buckets = SmiUntag(CAST(UnsafeLoadFixedArrayElement( |
| CAST(table), CollectionType::NumberOfBucketsIndex()))); |
| Node* const bucket = |
| WordAnd(hash, IntPtrSub(number_of_buckets, IntPtrConstant(1))); |
| Node* const first_entry = SmiUntag(CAST(UnsafeLoadFixedArrayElement( |
| CAST(table), bucket, |
| CollectionType::HashTableStartIndex() * kTaggedSize))); |
| |
| // Walk the bucket chain. |
| Node* entry_start; |
| Label if_key_found(this); |
| { |
| VARIABLE(var_entry, MachineType::PointerRepresentation(), first_entry); |
| Label loop(this, {&var_entry, entry_start_position}), |
| continue_next_entry(this); |
| Goto(&loop); |
| BIND(&loop); |
| |
| // If the entry index is the not-found sentinel, we are done. |
| GotoIf( |
| WordEqual(var_entry.value(), IntPtrConstant(CollectionType::kNotFound)), |
| not_found); |
| |
| // Make sure the entry index is within range. |
| CSA_ASSERT( |
| this, |
| UintPtrLessThan( |
| var_entry.value(), |
| SmiUntag(SmiAdd( |
| CAST(UnsafeLoadFixedArrayElement( |
| CAST(table), CollectionType::NumberOfElementsIndex())), |
| CAST(UnsafeLoadFixedArrayElement( |
| CAST(table), |
| CollectionType::NumberOfDeletedElementsIndex())))))); |
| |
| // Compute the index of the entry relative to kHashTableStartIndex. |
| entry_start = |
| IntPtrAdd(IntPtrMul(var_entry.value(), |
| IntPtrConstant(CollectionType::kEntrySize)), |
| number_of_buckets); |
| |
| // Load the key from the entry. |
| Node* const candidate_key = UnsafeLoadFixedArrayElement( |
| CAST(table), entry_start, |
| CollectionType::HashTableStartIndex() * kTaggedSize); |
| |
| key_compare(candidate_key, &if_key_found, &continue_next_entry); |
| |
| BIND(&continue_next_entry); |
| // Load the index of the next entry in the bucket chain. |
| var_entry.Bind(SmiUntag(CAST(UnsafeLoadFixedArrayElement( |
| CAST(table), entry_start, |
| (CollectionType::HashTableStartIndex() + CollectionType::kChainOffset) * |
| kTaggedSize)))); |
| |
| Goto(&loop); |
| } |
| |
| BIND(&if_key_found); |
| entry_start_position->Bind(entry_start); |
| Goto(entry_found); |
| } |
| |
| template void CodeStubAssembler::FindOrderedHashTableEntry<OrderedHashMap>( |
| Node* table, Node* hash, |
| const std::function<void(Node*, Label*, Label*)>& key_compare, |
| Variable* entry_start_position, Label* entry_found, Label* not_found); |
| template void CodeStubAssembler::FindOrderedHashTableEntry<OrderedHashSet>( |
| Node* table, Node* hash, |
| const std::function<void(Node*, Label*, Label*)>& key_compare, |
| Variable* entry_start_position, Label* entry_found, Label* not_found); |
| |
| Node* CodeStubAssembler::AllocateStruct(Node* map, AllocationFlags flags) { |
| Comment("AllocateStruct"); |
| CSA_ASSERT(this, IsMap(map)); |
| TNode<IntPtrT> size = TimesTaggedSize(LoadMapInstanceSizeInWords(map)); |
| TNode<Object> object = Allocate(size, flags); |
| StoreMapNoWriteBarrier(object, map); |
| InitializeStructBody(object, map, size, Struct::kHeaderSize); |
| return object; |
| } |
| |
| void CodeStubAssembler::InitializeStructBody(Node* object, Node* map, |
| Node* size, int start_offset) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| Comment("InitializeStructBody"); |
| Node* filler = UndefinedConstant(); |
| // Calculate the untagged field addresses. |
| object = BitcastTaggedToWord(object); |
| Node* start_address = |
| IntPtrAdd(object, IntPtrConstant(start_offset - kHeapObjectTag)); |
| Node* end_address = |
| IntPtrSub(IntPtrAdd(object, size), IntPtrConstant(kHeapObjectTag)); |
| StoreFieldsNoWriteBarrier(start_address, end_address, filler); |
| } |
| |
| Node* CodeStubAssembler::AllocateJSObjectFromMap( |
| Node* map, Node* properties, Node* elements, AllocationFlags flags, |
| SlackTrackingMode slack_tracking_mode) { |
| CSA_ASSERT(this, IsMap(map)); |
| CSA_ASSERT(this, Word32BinaryNot(IsJSFunctionMap(map))); |
| CSA_ASSERT(this, Word32BinaryNot(InstanceTypeEqual(LoadMapInstanceType(map), |
| JS_GLOBAL_OBJECT_TYPE))); |
| TNode<IntPtrT> instance_size = |
| TimesTaggedSize(LoadMapInstanceSizeInWords(map)); |
| TNode<Object> object = AllocateInNewSpace(instance_size, flags); |
| StoreMapNoWriteBarrier(object, map); |
| InitializeJSObjectFromMap(object, map, instance_size, properties, elements, |
| slack_tracking_mode); |
| return object; |
| } |
| |
| void CodeStubAssembler::InitializeJSObjectFromMap( |
| Node* object, Node* map, Node* instance_size, Node* properties, |
| Node* elements, SlackTrackingMode slack_tracking_mode) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| // This helper assumes that the object is in new-space, as guarded by the |
| // check in AllocatedJSObjectFromMap. |
| if (properties == nullptr) { |
| CSA_ASSERT(this, Word32BinaryNot(IsDictionaryMap((map)))); |
| StoreObjectFieldRoot(object, JSObject::kPropertiesOrHashOffset, |
| RootIndex::kEmptyFixedArray); |
| } else { |
| CSA_ASSERT(this, Word32Or(Word32Or(IsPropertyArray(properties), |
| IsNameDictionary(properties)), |
| IsEmptyFixedArray(properties))); |
| StoreObjectFieldNoWriteBarrier(object, JSObject::kPropertiesOrHashOffset, |
| properties); |
| } |
| if (elements == nullptr) { |
| StoreObjectFieldRoot(object, JSObject::kElementsOffset, |
| RootIndex::kEmptyFixedArray); |
| } else { |
| CSA_ASSERT(this, IsFixedArray(elements)); |
| StoreObjectFieldNoWriteBarrier(object, JSObject::kElementsOffset, elements); |
| } |
| if (slack_tracking_mode == kNoSlackTracking) { |
| InitializeJSObjectBodyNoSlackTracking(object, map, instance_size); |
| } else { |
| DCHECK_EQ(slack_tracking_mode, kWithSlackTracking); |
| InitializeJSObjectBodyWithSlackTracking(object, map, instance_size); |
| } |
| } |
| |
| void CodeStubAssembler::InitializeJSObjectBodyNoSlackTracking( |
| Node* object, Node* map, Node* instance_size, int start_offset) { |
| STATIC_ASSERT(Map::kNoSlackTracking == 0); |
| CSA_ASSERT( |
| this, IsClearWord32<Map::ConstructionCounterBits>(LoadMapBitField3(map))); |
| InitializeFieldsWithRoot(object, IntPtrConstant(start_offset), instance_size, |
| RootIndex::kUndefinedValue); |
| } |
| |
| void CodeStubAssembler::InitializeJSObjectBodyWithSlackTracking( |
| Node* object, Node* map, Node* instance_size) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| Comment("InitializeJSObjectBodyNoSlackTracking"); |
| |
| // Perform in-object slack tracking if requested. |
| int start_offset = JSObject::kHeaderSize; |
| Node* bit_field3 = LoadMapBitField3(map); |
| Label end(this), slack_tracking(this), complete(this, Label::kDeferred); |
| STATIC_ASSERT(Map::kNoSlackTracking == 0); |
| GotoIf(IsSetWord32<Map::ConstructionCounterBits>(bit_field3), |
| &slack_tracking); |
| Comment("No slack tracking"); |
| InitializeJSObjectBodyNoSlackTracking(object, map, instance_size); |
| Goto(&end); |
| |
| BIND(&slack_tracking); |
| { |
| Comment("Decrease construction counter"); |
| // Slack tracking is only done on initial maps. |
| CSA_ASSERT(this, IsUndefined(LoadMapBackPointer(map))); |
| STATIC_ASSERT(Map::ConstructionCounterBits::kNext == 32); |
| Node* new_bit_field3 = Int32Sub( |
| bit_field3, Int32Constant(1 << Map::ConstructionCounterBits::kShift)); |
| StoreObjectFieldNoWriteBarrier(map, Map::kBitField3Offset, new_bit_field3, |
| MachineRepresentation::kWord32); |
| STATIC_ASSERT(Map::kSlackTrackingCounterEnd == 1); |
| |
| // The object still has in-object slack therefore the |unsed_or_unused| |
| // field contain the "used" value. |
| Node* used_size = TimesTaggedSize(ChangeUint32ToWord( |
| LoadObjectField(map, Map::kUsedOrUnusedInstanceSizeInWordsOffset, |
| MachineType::Uint8()))); |
| |
| Comment("iInitialize filler fields"); |
| InitializeFieldsWithRoot(object, used_size, instance_size, |
| RootIndex::kOnePointerFillerMap); |
| |
| Comment("Initialize undefined fields"); |
| InitializeFieldsWithRoot(object, IntPtrConstant(start_offset), used_size, |
| RootIndex::kUndefinedValue); |
| |
| STATIC_ASSERT(Map::kNoSlackTracking == 0); |
| GotoIf(IsClearWord32<Map::ConstructionCounterBits>(new_bit_field3), |
| &complete); |
| Goto(&end); |
| } |
| |
| // Finalize the instance size. |
| BIND(&complete); |
| { |
| // ComplextInobjectSlackTracking doesn't allocate and thus doesn't need a |
| // context. |
| CallRuntime(Runtime::kCompleteInobjectSlackTrackingForMap, |
| NoContextConstant(), map); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| } |
| |
| void CodeStubAssembler::StoreFieldsNoWriteBarrier(Node* start_address, |
| Node* end_address, |
| Node* value) { |
| Comment("StoreFieldsNoWriteBarrier"); |
| CSA_ASSERT(this, WordIsAligned(start_address, kTaggedSize)); |
| CSA_ASSERT(this, WordIsAligned(end_address, kTaggedSize)); |
| BuildFastLoop( |
| start_address, end_address, |
| [this, value](Node* current) { |
| StoreNoWriteBarrier(MachineRepresentation::kTagged, current, value); |
| }, |
| kTaggedSize, INTPTR_PARAMETERS, IndexAdvanceMode::kPost); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsValidFastJSArrayCapacity( |
| Node* capacity, ParameterMode capacity_mode) { |
| return UncheckedCast<BoolT>( |
| UintPtrLessThanOrEqual(ParameterToIntPtr(capacity, capacity_mode), |
| IntPtrConstant(JSArray::kMaxFastArrayLength))); |
| } |
| |
| TNode<JSArray> CodeStubAssembler::AllocateJSArray( |
| TNode<Map> array_map, TNode<FixedArrayBase> elements, TNode<Smi> length, |
| Node* allocation_site) { |
| Comment("begin allocation of JSArray passing in elements"); |
| CSA_SLOW_ASSERT(this, TaggedIsPositiveSmi(length)); |
| |
| int base_size = JSArray::kSize; |
| if (allocation_site != nullptr) { |
| base_size += AllocationMemento::kSize; |
| } |
| |
| TNode<IntPtrT> size = IntPtrConstant(base_size); |
| TNode<JSArray> result = |
| AllocateUninitializedJSArray(array_map, length, allocation_site, size); |
| StoreObjectFieldNoWriteBarrier(result, JSArray::kElementsOffset, elements); |
| return result; |
| } |
| |
| std::pair<TNode<JSArray>, TNode<FixedArrayBase>> |
| CodeStubAssembler::AllocateUninitializedJSArrayWithElements( |
| ElementsKind kind, TNode<Map> array_map, TNode<Smi> length, |
| Node* allocation_site, Node* capacity, ParameterMode capacity_mode, |
| AllocationFlags allocation_flags) { |
| Comment("begin allocation of JSArray with elements"); |
| CHECK_EQ(allocation_flags & ~kAllowLargeObjectAllocation, 0); |
| CSA_SLOW_ASSERT(this, TaggedIsPositiveSmi(length)); |
| |
| TVARIABLE(JSArray, array); |
| TVARIABLE(FixedArrayBase, elements); |
| |
| if (IsIntPtrOrSmiConstantZero(capacity, capacity_mode)) { |
| TNode<FixedArrayBase> empty_array = EmptyFixedArrayConstant(); |
| array = AllocateJSArray(array_map, empty_array, length, allocation_site); |
| return {array.value(), empty_array}; |
| } |
| |
| Label out(this), empty(this), nonempty(this); |
| |
| Branch(SmiEqual(ParameterToTagged(capacity, capacity_mode), SmiConstant(0)), |
| &empty, &nonempty); |
| |
| BIND(&empty); |
| { |
| TNode<FixedArrayBase> empty_array = EmptyFixedArrayConstant(); |
| array = AllocateJSArray(array_map, empty_array, length, allocation_site); |
| elements = empty_array; |
| Goto(&out); |
| } |
| |
| BIND(&nonempty); |
| { |
| int base_size = JSArray::kSize; |
| if (allocation_site != nullptr) base_size += AllocationMemento::kSize; |
| |
| const int elements_offset = base_size; |
| |
| // Compute space for elements |
| base_size += FixedArray::kHeaderSize; |
| TNode<IntPtrT> size = |
| ElementOffsetFromIndex(capacity, kind, capacity_mode, base_size); |
| |
| // For very large arrays in which the requested allocation exceeds the |
| // maximal size of a regular heap object, we cannot use the allocation |
| // folding trick. Instead, we first allocate the elements in large object |
| // space, and then allocate the JSArray (and possibly the allocation |
| // memento) in new space. |
| if (allocation_flags & kAllowLargeObjectAllocation) { |
| Label next(this); |
| GotoIf(IsRegularHeapObjectSize(size), &next); |
| |
| CSA_CHECK(this, IsValidFastJSArrayCapacity(capacity, capacity_mode)); |
| |
| // Allocate and initialize the elements first. Full initialization is |
| // needed because the upcoming JSArray allocation could trigger GC. |
| elements = |
| AllocateFixedArray(kind, capacity, capacity_mode, allocation_flags); |
| |
| if (IsDoubleElementsKind(kind)) { |
| FillFixedDoubleArrayWithZero(CAST(elements.value()), |
| ParameterToIntPtr(capacity, capacity_mode)); |
| } else { |
| FillFixedArrayWithSmiZero(CAST(elements.value()), |
| ParameterToIntPtr(capacity, capacity_mode)); |
| } |
| |
| // The JSArray and possibly allocation memento next. Note that |
| // allocation_flags are *not* passed on here and the resulting JSArray |
| // will always be in new space. |
| array = |
| AllocateJSArray(array_map, elements.value(), length, allocation_site); |
| |
| Goto(&out); |
| |
| BIND(&next); |
| } |
| |
| // Fold all objects into a single new space allocation. |
| array = |
| AllocateUninitializedJSArray(array_map, length, allocation_site, size); |
| elements = UncheckedCast<FixedArrayBase>( |
| InnerAllocate(array.value(), elements_offset)); |
| |
| StoreObjectFieldNoWriteBarrier(array.value(), JSObject::kElementsOffset, |
| elements.value()); |
| |
| // Setup elements object. |
| STATIC_ASSERT(FixedArrayBase::kHeaderSize == 2 * kTaggedSize); |
| RootIndex elements_map_index = IsDoubleElementsKind(kind) |
| ? RootIndex::kFixedDoubleArrayMap |
| : RootIndex::kFixedArrayMap; |
| DCHECK(RootsTable::IsImmortalImmovable(elements_map_index)); |
| StoreMapNoWriteBarrier(elements.value(), elements_map_index); |
| |
| TNode<Smi> capacity_smi = ParameterToTagged(capacity, capacity_mode); |
| CSA_ASSERT(this, SmiGreaterThan(capacity_smi, SmiConstant(0))); |
| StoreObjectFieldNoWriteBarrier(elements.value(), FixedArray::kLengthOffset, |
| capacity_smi); |
| Goto(&out); |
| } |
| |
| BIND(&out); |
| return {array.value(), elements.value()}; |
| } |
| |
| TNode<JSArray> CodeStubAssembler::AllocateUninitializedJSArray( |
| TNode<Map> array_map, TNode<Smi> length, Node* allocation_site, |
| TNode<IntPtrT> size_in_bytes) { |
| CSA_SLOW_ASSERT(this, TaggedIsPositiveSmi(length)); |
| |
| // Allocate space for the JSArray and the elements FixedArray in one go. |
| TNode<Object> array = AllocateInNewSpace(size_in_bytes); |
| |
| StoreMapNoWriteBarrier(array, array_map); |
| StoreObjectFieldNoWriteBarrier(array, JSArray::kLengthOffset, length); |
| StoreObjectFieldRoot(array, JSArray::kPropertiesOrHashOffset, |
| RootIndex::kEmptyFixedArray); |
| |
| if (allocation_site != nullptr) { |
| InitializeAllocationMemento(array, IntPtrConstant(JSArray::kSize), |
| allocation_site); |
| } |
| |
| return CAST(array); |
| } |
| |
| TNode<JSArray> CodeStubAssembler::AllocateJSArray( |
| ElementsKind kind, TNode<Map> array_map, Node* capacity, TNode<Smi> length, |
| Node* allocation_site, ParameterMode capacity_mode, |
| AllocationFlags allocation_flags) { |
| CSA_SLOW_ASSERT(this, TaggedIsPositiveSmi(length)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(capacity, capacity_mode)); |
| |
| TNode<JSArray> array; |
| TNode<FixedArrayBase> elements; |
| |
| std::tie(array, elements) = AllocateUninitializedJSArrayWithElements( |
| kind, array_map, length, allocation_site, capacity, capacity_mode, |
| allocation_flags); |
| |
| Label out(this), nonempty(this); |
| |
| Branch(SmiEqual(ParameterToTagged(capacity, capacity_mode), SmiConstant(0)), |
| &out, &nonempty); |
| |
| BIND(&nonempty); |
| { |
| FillFixedArrayWithValue(kind, elements, |
| IntPtrOrSmiConstant(0, capacity_mode), capacity, |
| RootIndex::kTheHoleValue, capacity_mode); |
| Goto(&out); |
| } |
| |
| BIND(&out); |
| return array; |
| } |
| |
| Node* CodeStubAssembler::ExtractFastJSArray(Node* context, Node* array, |
| Node* begin, Node* count, |
| ParameterMode mode, Node* capacity, |
| Node* allocation_site) { |
| Node* original_array_map = LoadMap(array); |
| Node* elements_kind = LoadMapElementsKind(original_array_map); |
| |
| // Use the cannonical map for the Array's ElementsKind |
| Node* native_context = LoadNativeContext(context); |
| TNode<Map> array_map = LoadJSArrayElementsMap(elements_kind, native_context); |
| |
| TNode<FixedArrayBase> new_elements = ExtractFixedArray( |
| LoadElements(array), begin, count, capacity, |
| ExtractFixedArrayFlag::kAllFixedArrays, mode, nullptr, elements_kind); |
| |
| TNode<Object> result = AllocateJSArray( |
| array_map, new_elements, ParameterToTagged(count, mode), allocation_site); |
| return result; |
| } |
| |
| Node* CodeStubAssembler::CloneFastJSArray(Node* context, Node* array, |
| ParameterMode mode, |
| Node* allocation_site, |
| HoleConversionMode convert_holes) { |
| // TODO(dhai): we should be able to assert IsFastJSArray(array) here, but this |
| // function is also used to copy boilerplates even when the no-elements |
| // protector is invalid. This function should be renamed to reflect its uses. |
| CSA_ASSERT(this, IsJSArray(array)); |
| |
| Node* length = LoadJSArrayLength(array); |
| Node* new_elements = nullptr; |
| VARIABLE(var_new_elements, MachineRepresentation::kTagged); |
| TVARIABLE(Int32T, var_elements_kind, LoadMapElementsKind(LoadMap(array))); |
| |
| Label allocate_jsarray(this), holey_extract(this); |
| |
| bool need_conversion = |
| convert_holes == HoleConversionMode::kConvertToUndefined; |
| if (need_conversion) { |
| // We need to take care of holes, if the array is of holey elements kind. |
| GotoIf(IsHoleyFastElementsKind(var_elements_kind.value()), &holey_extract); |
| } |
| |
| // Simple extraction that preserves holes. |
| new_elements = |
| ExtractFixedArray(LoadElements(array), IntPtrOrSmiConstant(0, mode), |
| TaggedToParameter(length, mode), nullptr, |
| ExtractFixedArrayFlag::kAllFixedArraysDontCopyCOW, mode, |
| nullptr, var_elements_kind.value()); |
| var_new_elements.Bind(new_elements); |
| Goto(&allocate_jsarray); |
| |
| if (need_conversion) { |
| BIND(&holey_extract); |
| // Convert holes to undefined. |
| TVARIABLE(BoolT, var_holes_converted, Int32FalseConstant()); |
| // Copy |array|'s elements store. The copy will be compatible with the |
| // original elements kind unless there are holes in the source. Any holes |
| // get converted to undefined, hence in that case the copy is compatible |
| // only with PACKED_ELEMENTS and HOLEY_ELEMENTS, and we will choose |
| // PACKED_ELEMENTS. Also, if we want to replace holes, we must not use |
| // ExtractFixedArrayFlag::kDontCopyCOW. |
| new_elements = ExtractFixedArray( |
| LoadElements(array), IntPtrOrSmiConstant(0, mode), |
| TaggedToParameter(length, mode), nullptr, |
| ExtractFixedArrayFlag::kAllFixedArrays, mode, &var_holes_converted); |
| var_new_elements.Bind(new_elements); |
| // If the array type didn't change, use the original elements kind. |
| GotoIfNot(var_holes_converted.value(), &allocate_jsarray); |
| // Otherwise use PACKED_ELEMENTS for the target's elements kind. |
| var_elements_kind = Int32Constant(PACKED_ELEMENTS); |
| Goto(&allocate_jsarray); |
| } |
| |
| BIND(&allocate_jsarray); |
| // Use the cannonical map for the chosen elements kind. |
| Node* native_context = LoadNativeContext(context); |
| TNode<Map> array_map = |
| LoadJSArrayElementsMap(var_elements_kind.value(), native_context); |
| |
| TNode<Object> result = AllocateJSArray( |
| array_map, CAST(var_new_elements.value()), CAST(length), allocation_site); |
| return result; |
| } |
| |
| TNode<FixedArrayBase> CodeStubAssembler::AllocateFixedArray( |
| ElementsKind kind, Node* capacity, ParameterMode mode, |
| AllocationFlags flags, SloppyTNode<Map> fixed_array_map) { |
| Comment("AllocateFixedArray"); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(capacity, mode)); |
| CSA_ASSERT(this, IntPtrOrSmiGreaterThan(capacity, |
| IntPtrOrSmiConstant(0, mode), mode)); |
| |
| const intptr_t kMaxLength = IsDoubleElementsKind(kind) |
| ? FixedDoubleArray::kMaxLength |
| : FixedArray::kMaxLength; |
| intptr_t capacity_constant; |
| if (ToParameterConstant(capacity, &capacity_constant, mode)) { |
| CHECK_LE(capacity_constant, kMaxLength); |
| } else { |
| Label if_out_of_memory(this, Label::kDeferred), next(this); |
| Branch(IntPtrOrSmiGreaterThan( |
| capacity, |
| IntPtrOrSmiConstant(static_cast<int>(kMaxLength), mode), mode), |
| &if_out_of_memory, &next); |
| |
| BIND(&if_out_of_memory); |
| CallRuntime(Runtime::kFatalProcessOutOfMemoryInvalidArrayLength, |
| NoContextConstant()); |
| Unreachable(); |
| |
| BIND(&next); |
| } |
| |
| TNode<IntPtrT> total_size = GetFixedArrayAllocationSize(capacity, kind, mode); |
| |
| if (IsDoubleElementsKind(kind)) flags |= kDoubleAlignment; |
| // Allocate both array and elements object, and initialize the JSArray. |
| Node* array = Allocate(total_size, flags); |
| if (fixed_array_map != nullptr) { |
| // Conservatively only skip the write barrier if there are no allocation |
| // flags, this ensures that the object hasn't ended up in LOS. Note that the |
| // fixed array map is currently always immortal and technically wouldn't |
| // need the write barrier even in LOS, but it's better to not take chances |
| // in case this invariant changes later, since it's difficult to enforce |
| // locally here. |
| if (flags == CodeStubAssembler::kNone) { |
| StoreMapNoWriteBarrier(array, fixed_array_map); |
| } else { |
| StoreMap(array, fixed_array_map); |
| } |
| } else { |
| RootIndex map_index = IsDoubleElementsKind(kind) |
| ? RootIndex::kFixedDoubleArrayMap |
| : RootIndex::kFixedArrayMap; |
| DCHECK(RootsTable::IsImmortalImmovable(map_index)); |
| StoreMapNoWriteBarrier(array, map_index); |
| } |
| StoreObjectFieldNoWriteBarrier(array, FixedArray::kLengthOffset, |
| ParameterToTagged(capacity, mode)); |
| return UncheckedCast<FixedArray>(array); |
| } |
| |
| TNode<FixedArray> CodeStubAssembler::ExtractToFixedArray( |
| Node* source, Node* first, Node* count, Node* capacity, Node* source_map, |
| ElementsKind from_kind, AllocationFlags allocation_flags, |
| ExtractFixedArrayFlags extract_flags, ParameterMode parameter_mode, |
| HoleConversionMode convert_holes, TVariable<BoolT>* var_holes_converted, |
| Node* source_elements_kind) { |
| DCHECK_NE(first, nullptr); |
| DCHECK_NE(count, nullptr); |
| DCHECK_NE(capacity, nullptr); |
| DCHECK(extract_flags & ExtractFixedArrayFlag::kFixedArrays); |
| CSA_ASSERT(this, |
| WordNotEqual(IntPtrOrSmiConstant(0, parameter_mode), capacity)); |
| CSA_ASSERT(this, WordEqual(source_map, LoadMap(source))); |
| |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| VARIABLE(var_target_map, MachineRepresentation::kTagged, source_map); |
| |
| Label done(this, {&var_result}), is_cow(this), |
| new_space_check(this, {&var_target_map}); |
| |
| // If source_map is either FixedDoubleArrayMap, or FixedCOWArrayMap but |
| // we can't just use COW, use FixedArrayMap as the target map. Otherwise, use |
| // source_map as the target map. |
| if (IsDoubleElementsKind(from_kind)) { |
| CSA_ASSERT(this, IsFixedDoubleArrayMap(source_map)); |
| var_target_map.Bind(LoadRoot(RootIndex::kFixedArrayMap)); |
| Goto(&new_space_check); |
| } else { |
| CSA_ASSERT(this, Word32BinaryNot(IsFixedDoubleArrayMap(source_map))); |
| Branch(WordEqual(var_target_map.value(), |
| LoadRoot(RootIndex::kFixedCOWArrayMap)), |
| &is_cow, &new_space_check); |
| |
| BIND(&is_cow); |
| { |
| // |source| is a COW array, so we don't actually need to allocate a new |
| // array unless: |
| // 1) |extract_flags| forces us to, or |
| // 2) we're asked to extract only part of the |source| (|first| != 0). |
| if (extract_flags & ExtractFixedArrayFlag::kDontCopyCOW) { |
| Branch(WordNotEqual(IntPtrOrSmiConstant(0, parameter_mode), first), |
| &new_space_check, [&] { |
| var_result.Bind(source); |
| Goto(&done); |
| }); |
| } else { |
| var_target_map.Bind(LoadRoot(RootIndex::kFixedArrayMap)); |
| Goto(&new_space_check); |
| } |
| } |
| } |
| |
| BIND(&new_space_check); |
| { |
| bool handle_old_space = true; |
| if (extract_flags & ExtractFixedArrayFlag::kNewSpaceAllocationOnly) { |
| handle_old_space = false; |
| CSA_ASSERT(this, Word32BinaryNot(FixedArraySizeDoesntFitInNewSpace( |
| count, FixedArray::kHeaderSize, parameter_mode))); |
| } else { |
| int constant_count; |
| handle_old_space = |
| !TryGetIntPtrOrSmiConstantValue(count, &constant_count, |
| parameter_mode) || |
| (constant_count > |
| FixedArray::GetMaxLengthForNewSpaceAllocation(PACKED_ELEMENTS)); |
| } |
| |
| Label old_space(this, Label::kDeferred); |
| if (handle_old_space) { |
| GotoIfFixedArraySizeDoesntFitInNewSpace( |
| capacity, &old_space, FixedArray::kHeaderSize, parameter_mode); |
| } |
| |
| Comment("Copy FixedArray new space"); |
| // We use PACKED_ELEMENTS to tell AllocateFixedArray and |
| // CopyFixedArrayElements that we want a FixedArray. |
| const ElementsKind to_kind = PACKED_ELEMENTS; |
| TNode<FixedArrayBase> to_elements = |
| AllocateFixedArray(to_kind, capacity, parameter_mode, |
| AllocationFlag::kNone, var_target_map.value()); |
| var_result.Bind(to_elements); |
| |
| if (convert_holes == HoleConversionMode::kDontConvert && |
| !IsDoubleElementsKind(from_kind)) { |
| // We can use CopyElements (memcpy) because we don't need to replace or |
| // convert any values. Since {to_elements} is in new-space, CopyElements |
| // will efficiently use memcpy. |
| FillFixedArrayWithValue(to_kind, to_elements, count, capacity, |
| RootIndex::kTheHoleValue, parameter_mode); |
| CopyElements(to_kind, to_elements, IntPtrConstant(0), CAST(source), |
| ParameterToIntPtr(first, parameter_mode), |
| ParameterToIntPtr(count, parameter_mode), |
| SKIP_WRITE_BARRIER); |
| } else { |
| CopyFixedArrayElements(from_kind, source, to_kind, to_elements, first, |
| count, capacity, SKIP_WRITE_BARRIER, |
| parameter_mode, convert_holes, |
| var_holes_converted); |
| } |
| Goto(&done); |
| |
| if (handle_old_space) { |
| BIND(&old_space); |
| { |
| Comment("Copy FixedArray old space"); |
| Label copy_one_by_one(this); |
| |
| // Try to use memcpy if we don't need to convert holes to undefined. |
| if (convert_holes == HoleConversionMode::kDontConvert && |
| source_elements_kind != nullptr) { |
| // Only try memcpy if we're not copying object pointers. |
| GotoIfNot(IsFastSmiElementsKind(source_elements_kind), |
| ©_one_by_one); |
| |
| const ElementsKind to_smi_kind = PACKED_SMI_ELEMENTS; |
| to_elements = |
| AllocateFixedArray(to_smi_kind, capacity, parameter_mode, |
| allocation_flags, var_target_map.value()); |
| var_result.Bind(to_elements); |
| |
| FillFixedArrayWithValue(to_smi_kind, to_elements, count, capacity, |
| RootIndex::kTheHoleValue, parameter_mode); |
| // CopyElements will try to use memcpy if it's not conflicting with |
| // GC. Otherwise it will copy elements by elements, but skip write |
| // barriers (since we're copying smis to smis). |
| CopyElements(to_smi_kind, to_elements, IntPtrConstant(0), |
| CAST(source), ParameterToIntPtr(first, parameter_mode), |
| ParameterToIntPtr(count, parameter_mode), |
| SKIP_WRITE_BARRIER); |
| Goto(&done); |
| } else { |
| Goto(©_one_by_one); |
| } |
| |
| BIND(©_one_by_one); |
| { |
| to_elements = |
| AllocateFixedArray(to_kind, capacity, parameter_mode, |
| allocation_flags, var_target_map.value()); |
| var_result.Bind(to_elements); |
| CopyFixedArrayElements(from_kind, source, to_kind, to_elements, first, |
| count, capacity, UPDATE_WRITE_BARRIER, |
| parameter_mode, convert_holes, |
| var_holes_converted); |
| Goto(&done); |
| } |
| } |
| } |
| } |
| |
| BIND(&done); |
| return UncheckedCast<FixedArray>(var_result.value()); |
| } |
| |
| TNode<FixedArrayBase> CodeStubAssembler::ExtractFixedDoubleArrayFillingHoles( |
| Node* from_array, Node* first, Node* count, Node* capacity, |
| Node* fixed_array_map, TVariable<BoolT>* var_holes_converted, |
| AllocationFlags allocation_flags, ExtractFixedArrayFlags extract_flags, |
| ParameterMode mode) { |
| DCHECK_NE(first, nullptr); |
| DCHECK_NE(count, nullptr); |
| DCHECK_NE(capacity, nullptr); |
| DCHECK_NE(var_holes_converted, nullptr); |
| CSA_ASSERT(this, IsFixedDoubleArrayMap(fixed_array_map)); |
| |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| const ElementsKind kind = PACKED_DOUBLE_ELEMENTS; |
| Node* to_elements = AllocateFixedArray(kind, capacity, mode, allocation_flags, |
| fixed_array_map); |
| var_result.Bind(to_elements); |
| // We first try to copy the FixedDoubleArray to a new FixedDoubleArray. |
| // |var_holes_converted| is set to False preliminarily. |
| *var_holes_converted = Int32FalseConstant(); |
| |
| // The construction of the loop and the offsets for double elements is |
| // extracted from CopyFixedArrayElements. |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(count, mode)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(capacity, mode)); |
| CSA_SLOW_ASSERT(this, IsFixedArrayWithKindOrEmpty(from_array, kind)); |
| STATIC_ASSERT(FixedArray::kHeaderSize == FixedDoubleArray::kHeaderSize); |
| |
| Comment("[ ExtractFixedDoubleArrayFillingHoles"); |
| |
| // This copy can trigger GC, so we pre-initialize the array with holes. |
| FillFixedArrayWithValue(kind, to_elements, IntPtrOrSmiConstant(0, mode), |
| capacity, RootIndex::kTheHoleValue, mode); |
| |
| const int first_element_offset = FixedArray::kHeaderSize - kHeapObjectTag; |
| Node* first_from_element_offset = |
| ElementOffsetFromIndex(first, kind, mode, 0); |
| Node* limit_offset = IntPtrAdd(first_from_element_offset, |
| IntPtrConstant(first_element_offset)); |
| VARIABLE(var_from_offset, MachineType::PointerRepresentation(), |
| ElementOffsetFromIndex(IntPtrOrSmiAdd(first, count, mode), kind, |
| mode, first_element_offset)); |
| |
| Label decrement(this, {&var_from_offset}), done(this); |
| Node* to_array_adjusted = |
| IntPtrSub(BitcastTaggedToWord(to_elements), first_from_element_offset); |
| |
| Branch(WordEqual(var_from_offset.value(), limit_offset), &done, &decrement); |
| |
| BIND(&decrement); |
| { |
| Node* from_offset = |
| IntPtrSub(var_from_offset.value(), IntPtrConstant(kDoubleSize)); |
| var_from_offset.Bind(from_offset); |
| |
| Node* to_offset = from_offset; |
| |
| Label if_hole(this); |
| |
| Node* value = LoadElementAndPrepareForStore( |
| from_array, var_from_offset.value(), kind, kind, &if_hole); |
| |
| StoreNoWriteBarrier(MachineRepresentation::kFloat64, to_array_adjusted, |
| to_offset, value); |
| |
| Node* compare = WordNotEqual(from_offset, limit_offset); |
| Branch(compare, &decrement, &done); |
| |
| BIND(&if_hole); |
| // We are unlucky: there are holes! We need to restart the copy, this time |
| // we will copy the FixedDoubleArray to a new FixedArray with undefined |
| // replacing holes. We signal this to the caller through |
| // |var_holes_converted|. |
| *var_holes_converted = Int32TrueConstant(); |
| to_elements = |
| ExtractToFixedArray(from_array, first, count, capacity, fixed_array_map, |
| kind, allocation_flags, extract_flags, mode, |
| HoleConversionMode::kConvertToUndefined); |
| var_result.Bind(to_elements); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| Comment("] ExtractFixedDoubleArrayFillingHoles"); |
| return UncheckedCast<FixedArrayBase>(var_result.value()); |
| } |
| |
| TNode<FixedArrayBase> CodeStubAssembler::ExtractFixedArray( |
| Node* source, Node* first, Node* count, Node* capacity, |
| ExtractFixedArrayFlags extract_flags, ParameterMode parameter_mode, |
| TVariable<BoolT>* var_holes_converted, Node* source_runtime_kind) { |
| DCHECK(extract_flags & ExtractFixedArrayFlag::kFixedArrays || |
| extract_flags & ExtractFixedArrayFlag::kFixedDoubleArrays); |
| // If we want to replace holes, ExtractFixedArrayFlag::kDontCopyCOW should not |
| // be used, because that disables the iteration which detects holes. |
| DCHECK_IMPLIES(var_holes_converted != nullptr, |
| !(extract_flags & ExtractFixedArrayFlag::kDontCopyCOW)); |
| HoleConversionMode convert_holes = |
| var_holes_converted != nullptr ? HoleConversionMode::kConvertToUndefined |
| : HoleConversionMode::kDontConvert; |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| const AllocationFlags allocation_flags = |
| (extract_flags & ExtractFixedArrayFlag::kNewSpaceAllocationOnly) |
| ? CodeStubAssembler::kNone |
| : CodeStubAssembler::kAllowLargeObjectAllocation; |
| if (first == nullptr) { |
| first = IntPtrOrSmiConstant(0, parameter_mode); |
| } |
| if (count == nullptr) { |
| count = IntPtrOrSmiSub( |
| TaggedToParameter(LoadFixedArrayBaseLength(source), parameter_mode), |
| first, parameter_mode); |
| |
| CSA_ASSERT( |
| this, IntPtrOrSmiLessThanOrEqual(IntPtrOrSmiConstant(0, parameter_mode), |
| count, parameter_mode)); |
| } |
| if (capacity == nullptr) { |
| capacity = count; |
| } else { |
| CSA_ASSERT(this, Word32BinaryNot(IntPtrOrSmiGreaterThan( |
| IntPtrOrSmiAdd(first, count, parameter_mode), capacity, |
| parameter_mode))); |
| } |
| |
| Label if_fixed_double_array(this), empty(this), done(this, {&var_result}); |
| Node* source_map = LoadMap(source); |
| GotoIf(WordEqual(IntPtrOrSmiConstant(0, parameter_mode), capacity), &empty); |
| |
| if (extract_flags & ExtractFixedArrayFlag::kFixedDoubleArrays) { |
| if (extract_flags & ExtractFixedArrayFlag::kFixedArrays) { |
| GotoIf(IsFixedDoubleArrayMap(source_map), &if_fixed_double_array); |
| } else { |
| CSA_ASSERT(this, IsFixedDoubleArrayMap(source_map)); |
| } |
| } |
| |
| if (extract_flags & ExtractFixedArrayFlag::kFixedArrays) { |
| // Here we can only get |source| as FixedArray, never FixedDoubleArray. |
| // PACKED_ELEMENTS is used to signify that the source is a FixedArray. |
| Node* to_elements = ExtractToFixedArray( |
| source, first, count, capacity, source_map, PACKED_ELEMENTS, |
| allocation_flags, extract_flags, parameter_mode, convert_holes, |
| var_holes_converted, source_runtime_kind); |
| var_result.Bind(to_elements); |
| Goto(&done); |
| } |
| |
| if (extract_flags & ExtractFixedArrayFlag::kFixedDoubleArrays) { |
| BIND(&if_fixed_double_array); |
| Comment("Copy FixedDoubleArray"); |
| |
| if (convert_holes == HoleConversionMode::kConvertToUndefined) { |
| Node* to_elements = ExtractFixedDoubleArrayFillingHoles( |
| source, first, count, capacity, source_map, var_holes_converted, |
| allocation_flags, extract_flags, parameter_mode); |
| var_result.Bind(to_elements); |
| } else { |
| // We use PACKED_DOUBLE_ELEMENTS to signify that both the source and |
| // the target are FixedDoubleArray. That it is PACKED or HOLEY does not |
| // matter. |
| ElementsKind kind = PACKED_DOUBLE_ELEMENTS; |
| TNode<FixedArrayBase> to_elements = AllocateFixedArray( |
| kind, capacity, parameter_mode, allocation_flags, source_map); |
| FillFixedArrayWithValue(kind, to_elements, count, capacity, |
| RootIndex::kTheHoleValue, parameter_mode); |
| CopyElements(kind, to_elements, IntPtrConstant(0), CAST(source), |
| ParameterToIntPtr(first, parameter_mode), |
| ParameterToIntPtr(count, parameter_mode)); |
| var_result.Bind(to_elements); |
| } |
| |
| Goto(&done); |
| } |
| |
| BIND(&empty); |
| { |
| Comment("Copy empty array"); |
| |
| var_result.Bind(EmptyFixedArrayConstant()); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return UncheckedCast<FixedArray>(var_result.value()); |
| } |
| |
| void CodeStubAssembler::InitializePropertyArrayLength(Node* property_array, |
| Node* length, |
| ParameterMode mode) { |
| CSA_SLOW_ASSERT(this, IsPropertyArray(property_array)); |
| CSA_ASSERT( |
| this, IntPtrOrSmiGreaterThan(length, IntPtrOrSmiConstant(0, mode), mode)); |
| CSA_ASSERT( |
| this, |
| IntPtrOrSmiLessThanOrEqual( |
| length, IntPtrOrSmiConstant(PropertyArray::LengthField::kMax, mode), |
| mode)); |
| StoreObjectFieldNoWriteBarrier( |
| property_array, PropertyArray::kLengthAndHashOffset, |
| ParameterToTagged(length, mode), MachineRepresentation::kTaggedSigned); |
| } |
| |
| Node* CodeStubAssembler::AllocatePropertyArray(Node* capacity_node, |
| ParameterMode mode, |
| AllocationFlags flags) { |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(capacity_node, mode)); |
| CSA_ASSERT(this, IntPtrOrSmiGreaterThan(capacity_node, |
| IntPtrOrSmiConstant(0, mode), mode)); |
| TNode<IntPtrT> total_size = |
| GetPropertyArrayAllocationSize(capacity_node, mode); |
| |
| TNode<Object> array = Allocate(total_size, flags); |
| RootIndex map_index = RootIndex::kPropertyArrayMap; |
| DCHECK(RootsTable::IsImmortalImmovable(map_index)); |
| StoreMapNoWriteBarrier(array, map_index); |
| InitializePropertyArrayLength(array, capacity_node, mode); |
| return array; |
| } |
| |
| void CodeStubAssembler::FillPropertyArrayWithUndefined(Node* array, |
| Node* from_node, |
| Node* to_node, |
| ParameterMode mode) { |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(from_node, mode)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(to_node, mode)); |
| CSA_SLOW_ASSERT(this, IsPropertyArray(array)); |
| ElementsKind kind = PACKED_ELEMENTS; |
| Node* value = UndefinedConstant(); |
| BuildFastFixedArrayForEach(array, kind, from_node, to_node, |
| [this, value](Node* array, Node* offset) { |
| StoreNoWriteBarrier( |
| MachineRepresentation::kTagged, array, |
| offset, value); |
| }, |
| mode); |
| } |
| |
| void CodeStubAssembler::FillFixedArrayWithValue(ElementsKind kind, Node* array, |
| Node* from_node, Node* to_node, |
| RootIndex value_root_index, |
| ParameterMode mode) { |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(from_node, mode)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(to_node, mode)); |
| CSA_SLOW_ASSERT(this, IsFixedArrayWithKind(array, kind)); |
| DCHECK(value_root_index == RootIndex::kTheHoleValue || |
| value_root_index == RootIndex::kUndefinedValue); |
| |
| // Determine the value to initialize the {array} based |
| // on the {value_root_index} and the elements {kind}. |
| Node* value = LoadRoot(value_root_index); |
| if (IsDoubleElementsKind(kind)) { |
| value = LoadHeapNumberValue(value); |
| } |
| |
| BuildFastFixedArrayForEach( |
| array, kind, from_node, to_node, |
| [this, value, kind](Node* array, Node* offset) { |
| if (IsDoubleElementsKind(kind)) { |
| StoreNoWriteBarrier(MachineRepresentation::kFloat64, array, offset, |
| value); |
| } else { |
| StoreNoWriteBarrier(MachineRepresentation::kTagged, array, offset, |
| value); |
| } |
| }, |
| mode); |
| } |
| |
| void CodeStubAssembler::StoreFixedDoubleArrayHole( |
| TNode<FixedDoubleArray> array, Node* index, ParameterMode parameter_mode) { |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(index, parameter_mode)); |
| Node* offset = |
| ElementOffsetFromIndex(index, PACKED_DOUBLE_ELEMENTS, parameter_mode, |
| FixedArray::kHeaderSize - kHeapObjectTag); |
| CSA_ASSERT(this, IsOffsetInBounds( |
| offset, LoadAndUntagFixedArrayBaseLength(array), |
| FixedDoubleArray::kHeaderSize, PACKED_DOUBLE_ELEMENTS)); |
| Node* double_hole = |
| Is64() ? ReinterpretCast<UintPtrT>(Int64Constant(kHoleNanInt64)) |
| : ReinterpretCast<UintPtrT>(Int32Constant(kHoleNanLower32)); |
| // TODO(danno): When we have a Float32/Float64 wrapper class that |
| // preserves double bits during manipulation, remove this code/change |
| // this to an indexed Float64 store. |
| if (Is64()) { |
| StoreNoWriteBarrier(MachineRepresentation::kWord64, array, offset, |
| double_hole); |
| } else { |
| StoreNoWriteBarrier(MachineRepresentation::kWord32, array, offset, |
| double_hole); |
| StoreNoWriteBarrier(MachineRepresentation::kWord32, array, |
| IntPtrAdd(offset, IntPtrConstant(kInt32Size)), |
| double_hole); |
| } |
| } |
| |
| void CodeStubAssembler::FillFixedArrayWithSmiZero(TNode<FixedArray> array, |
| TNode<IntPtrT> length) { |
| CSA_ASSERT(this, WordEqual(length, LoadAndUntagFixedArrayBaseLength(array))); |
| |
| TNode<IntPtrT> byte_length = TimesTaggedSize(length); |
| CSA_ASSERT(this, UintPtrLessThan(length, byte_length)); |
| |
| static const int32_t fa_base_data_offset = |
| FixedArray::kHeaderSize - kHeapObjectTag; |
| TNode<IntPtrT> backing_store = IntPtrAdd(BitcastTaggedToWord(array), |
| IntPtrConstant(fa_base_data_offset)); |
| |
| // Call out to memset to perform initialization. |
| TNode<ExternalReference> memset = |
| ExternalConstant(ExternalReference::libc_memset_function()); |
| STATIC_ASSERT(kSizetSize == kIntptrSize); |
| CallCFunction3(MachineType::Pointer(), MachineType::Pointer(), |
| MachineType::IntPtr(), MachineType::UintPtr(), memset, |
| backing_store, IntPtrConstant(0), byte_length); |
| } |
| |
| void CodeStubAssembler::FillFixedDoubleArrayWithZero( |
| TNode<FixedDoubleArray> array, TNode<IntPtrT> length) { |
| CSA_ASSERT(this, WordEqual(length, LoadAndUntagFixedArrayBaseLength(array))); |
| |
| TNode<IntPtrT> byte_length = TimesDoubleSize(length); |
| CSA_ASSERT(this, UintPtrLessThan(length, byte_length)); |
| |
| static const int32_t fa_base_data_offset = |
| FixedDoubleArray::kHeaderSize - kHeapObjectTag; |
| TNode<IntPtrT> backing_store = IntPtrAdd(BitcastTaggedToWord(array), |
| IntPtrConstant(fa_base_data_offset)); |
| |
| // Call out to memset to perform initialization. |
| TNode<ExternalReference> memset = |
| ExternalConstant(ExternalReference::libc_memset_function()); |
| STATIC_ASSERT(kSizetSize == kIntptrSize); |
| CallCFunction3(MachineType::Pointer(), MachineType::Pointer(), |
| MachineType::IntPtr(), MachineType::UintPtr(), memset, |
| backing_store, IntPtrConstant(0), byte_length); |
| } |
| |
| void CodeStubAssembler::JumpIfPointersFromHereAreInteresting( |
| TNode<Object> object, Label* interesting) { |
| Label finished(this); |
| TNode<IntPtrT> object_word = BitcastTaggedToWord(object); |
| TNode<IntPtrT> object_page = PageFromAddress(object_word); |
| TNode<IntPtrT> page_flags = UncheckedCast<IntPtrT>(Load( |
| MachineType::IntPtr(), object_page, IntPtrConstant(Page::kFlagsOffset))); |
| Branch( |
| WordEqual(WordAnd(page_flags, |
| IntPtrConstant( |
| MemoryChunk::kPointersFromHereAreInterestingMask)), |
| IntPtrConstant(0)), |
| &finished, interesting); |
| BIND(&finished); |
| } |
| |
| void CodeStubAssembler::MoveElements(ElementsKind kind, |
| TNode<FixedArrayBase> elements, |
| TNode<IntPtrT> dst_index, |
| TNode<IntPtrT> src_index, |
| TNode<IntPtrT> length) { |
| Label finished(this); |
| Label needs_barrier(this); |
| const bool needs_barrier_check = !IsDoubleElementsKind(kind); |
| |
| DCHECK(IsFastElementsKind(kind)); |
| CSA_ASSERT(this, IsFixedArrayWithKind(elements, kind)); |
| CSA_ASSERT(this, |
| IntPtrLessThanOrEqual(IntPtrAdd(dst_index, length), |
| LoadAndUntagFixedArrayBaseLength(elements))); |
| CSA_ASSERT(this, |
| IntPtrLessThanOrEqual(IntPtrAdd(src_index, length), |
| LoadAndUntagFixedArrayBaseLength(elements))); |
| |
| // The write barrier can be ignored if {dst_elements} is in new space, or if |
| // the elements pointer is FixedDoubleArray. |
| if (needs_barrier_check) { |
| JumpIfPointersFromHereAreInteresting(elements, &needs_barrier); |
| } |
| |
| const TNode<IntPtrT> source_byte_length = |
| IntPtrMul(length, IntPtrConstant(ElementsKindToByteSize(kind))); |
| static const int32_t fa_base_data_offset = |
| FixedArrayBase::kHeaderSize - kHeapObjectTag; |
| TNode<IntPtrT> elements_intptr = BitcastTaggedToWord(elements); |
| TNode<IntPtrT> target_data_ptr = |
| IntPtrAdd(elements_intptr, |
| ElementOffsetFromIndex(dst_index, kind, INTPTR_PARAMETERS, |
| fa_base_data_offset)); |
| TNode<IntPtrT> source_data_ptr = |
| IntPtrAdd(elements_intptr, |
| ElementOffsetFromIndex(src_index, kind, INTPTR_PARAMETERS, |
| fa_base_data_offset)); |
| TNode<ExternalReference> memmove = |
| ExternalConstant(ExternalReference::libc_memmove_function()); |
| CallCFunction3(MachineType::Pointer(), MachineType::Pointer(), |
| MachineType::Pointer(), MachineType::UintPtr(), memmove, |
| target_data_ptr, source_data_ptr, source_byte_length); |
| |
| if (needs_barrier_check) { |
| Goto(&finished); |
| |
| BIND(&needs_barrier); |
| { |
| const TNode<IntPtrT> begin = src_index; |
| const TNode<IntPtrT> end = IntPtrAdd(begin, length); |
| |
| // If dst_index is less than src_index, then walk forward. |
| const TNode<IntPtrT> delta = |
| IntPtrMul(IntPtrSub(dst_index, begin), |
| IntPtrConstant(ElementsKindToByteSize(kind))); |
| auto loop_body = [&](Node* array, Node* offset) { |
| Node* const element = Load(MachineType::AnyTagged(), array, offset); |
| Node* const delta_offset = IntPtrAdd(offset, delta); |
| Store(array, delta_offset, element); |
| }; |
| |
| Label iterate_forward(this); |
| Label iterate_backward(this); |
| Branch(IntPtrLessThan(delta, IntPtrConstant(0)), &iterate_forward, |
| &iterate_backward); |
| BIND(&iterate_forward); |
| { |
| // Make a loop for the stores. |
| BuildFastFixedArrayForEach(elements, kind, begin, end, loop_body, |
| INTPTR_PARAMETERS, |
| ForEachDirection::kForward); |
| Goto(&finished); |
| } |
| |
| BIND(&iterate_backward); |
| { |
| BuildFastFixedArrayForEach(elements, kind, begin, end, loop_body, |
| INTPTR_PARAMETERS, |
| ForEachDirection::kReverse); |
| Goto(&finished); |
| } |
| } |
| BIND(&finished); |
| } |
| } |
| |
| void CodeStubAssembler::CopyElements(ElementsKind kind, |
| TNode<FixedArrayBase> dst_elements, |
| TNode<IntPtrT> dst_index, |
| TNode<FixedArrayBase> src_elements, |
| TNode<IntPtrT> src_index, |
| TNode<IntPtrT> length, |
| WriteBarrierMode write_barrier) { |
| Label finished(this); |
| Label needs_barrier(this); |
| const bool needs_barrier_check = !IsDoubleElementsKind(kind); |
| |
| DCHECK(IsFastElementsKind(kind)); |
| CSA_ASSERT(this, IsFixedArrayWithKind(dst_elements, kind)); |
| CSA_ASSERT(this, IsFixedArrayWithKind(src_elements, kind)); |
| CSA_ASSERT(this, IntPtrLessThanOrEqual( |
| IntPtrAdd(dst_index, length), |
| LoadAndUntagFixedArrayBaseLength(dst_elements))); |
| CSA_ASSERT(this, IntPtrLessThanOrEqual( |
| IntPtrAdd(src_index, length), |
| LoadAndUntagFixedArrayBaseLength(src_elements))); |
| CSA_ASSERT(this, Word32Or(WordNotEqual(dst_elements, src_elements), |
| WordEqual(length, IntPtrConstant(0)))); |
| |
| // The write barrier can be ignored if {dst_elements} is in new space, or if |
| // the elements pointer is FixedDoubleArray. |
| if (needs_barrier_check) { |
| JumpIfPointersFromHereAreInteresting(dst_elements, &needs_barrier); |
| } |
| |
| TNode<IntPtrT> source_byte_length = |
| IntPtrMul(length, IntPtrConstant(ElementsKindToByteSize(kind))); |
| static const int32_t fa_base_data_offset = |
| FixedArrayBase::kHeaderSize - kHeapObjectTag; |
| TNode<IntPtrT> src_offset_start = ElementOffsetFromIndex( |
| src_index, kind, INTPTR_PARAMETERS, fa_base_data_offset); |
| TNode<IntPtrT> dst_offset_start = ElementOffsetFromIndex( |
| dst_index, kind, INTPTR_PARAMETERS, fa_base_data_offset); |
| TNode<IntPtrT> src_elements_intptr = BitcastTaggedToWord(src_elements); |
| TNode<IntPtrT> source_data_ptr = |
| IntPtrAdd(src_elements_intptr, src_offset_start); |
| TNode<IntPtrT> dst_elements_intptr = BitcastTaggedToWord(dst_elements); |
| TNode<IntPtrT> dst_data_ptr = |
| IntPtrAdd(dst_elements_intptr, dst_offset_start); |
| TNode<ExternalReference> memcpy = |
| ExternalConstant(ExternalReference::libc_memcpy_function()); |
| CallCFunction3(MachineType::Pointer(), MachineType::Pointer(), |
| MachineType::Pointer(), MachineType::UintPtr(), memcpy, |
| dst_data_ptr, source_data_ptr, source_byte_length); |
| |
| if (needs_barrier_check) { |
| Goto(&finished); |
| |
| BIND(&needs_barrier); |
| { |
| const TNode<IntPtrT> begin = src_index; |
| const TNode<IntPtrT> end = IntPtrAdd(begin, length); |
| const TNode<IntPtrT> delta = |
| IntPtrMul(IntPtrSub(dst_index, src_index), |
| IntPtrConstant(ElementsKindToByteSize(kind))); |
| BuildFastFixedArrayForEach( |
| src_elements, kind, begin, end, |
| [&](Node* array, Node* offset) { |
| Node* const element = Load(MachineType::AnyTagged(), array, offset); |
| Node* const delta_offset = IntPtrAdd(offset, delta); |
| if (write_barrier == SKIP_WRITE_BARRIER) { |
| StoreNoWriteBarrier(MachineRepresentation::kTagged, dst_elements, |
| delta_offset, element); |
| } else { |
| Store(dst_elements, delta_offset, element); |
| } |
| }, |
| INTPTR_PARAMETERS, ForEachDirection::kForward); |
| Goto(&finished); |
| } |
| BIND(&finished); |
| } |
| } |
| |
| void CodeStubAssembler::CopyFixedArrayElements( |
| ElementsKind from_kind, Node* from_array, ElementsKind to_kind, |
| Node* to_array, Node* first_element, Node* element_count, Node* capacity, |
| WriteBarrierMode barrier_mode, ParameterMode mode, |
| HoleConversionMode convert_holes, TVariable<BoolT>* var_holes_converted) { |
| DCHECK_IMPLIES(var_holes_converted != nullptr, |
| convert_holes == HoleConversionMode::kConvertToUndefined); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(element_count, mode)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(capacity, mode)); |
| CSA_SLOW_ASSERT(this, IsFixedArrayWithKindOrEmpty(from_array, from_kind)); |
| CSA_SLOW_ASSERT(this, IsFixedArrayWithKindOrEmpty(to_array, to_kind)); |
| STATIC_ASSERT(FixedArray::kHeaderSize == FixedDoubleArray::kHeaderSize); |
| const int first_element_offset = FixedArray::kHeaderSize - kHeapObjectTag; |
| Comment("[ CopyFixedArrayElements"); |
| |
| // Typed array elements are not supported. |
| DCHECK(!IsFixedTypedArrayElementsKind(from_kind)); |
| DCHECK(!IsFixedTypedArrayElementsKind(to_kind)); |
| |
| Label done(this); |
| bool from_double_elements = IsDoubleElementsKind(from_kind); |
| bool to_double_elements = IsDoubleElementsKind(to_kind); |
| bool doubles_to_objects_conversion = |
| IsDoubleElementsKind(from_kind) && IsObjectElementsKind(to_kind); |
| bool needs_write_barrier = |
| doubles_to_objects_conversion || |
| (barrier_mode == UPDATE_WRITE_BARRIER && IsObjectElementsKind(to_kind)); |
| bool element_offset_matches = |
| !needs_write_barrier && |
| (kTaggedSize == kDoubleSize || |
| IsDoubleElementsKind(from_kind) == IsDoubleElementsKind(to_kind)); |
| Node* double_hole = |
| Is64() ? ReinterpretCast<UintPtrT>(Int64Constant(kHoleNanInt64)) |
| : ReinterpretCast<UintPtrT>(Int32Constant(kHoleNanLower32)); |
| |
| // If copying might trigger a GC, we pre-initialize the FixedArray such that |
| // it's always in a consistent state. |
| if (convert_holes == HoleConversionMode::kConvertToUndefined) { |
| DCHECK(IsObjectElementsKind(to_kind)); |
| // Use undefined for the part that we copy and holes for the rest. |
| // Later if we run into a hole in the source we can just skip the writing |
| // to the target and are still guaranteed that we get an undefined. |
| FillFixedArrayWithValue(to_kind, to_array, IntPtrOrSmiConstant(0, mode), |
| element_count, RootIndex::kUndefinedValue, mode); |
| FillFixedArrayWithValue(to_kind, to_array, element_count, capacity, |
| RootIndex::kTheHoleValue, mode); |
| } else if (doubles_to_objects_conversion) { |
| // Pre-initialized the target with holes so later if we run into a hole in |
| // the source we can just skip the writing to the target. |
| FillFixedArrayWithValue(to_kind, to_array, IntPtrOrSmiConstant(0, mode), |
| capacity, RootIndex::kTheHoleValue, mode); |
| } else if (element_count != capacity) { |
| FillFixedArrayWithValue(to_kind, to_array, element_count, capacity, |
| RootIndex::kTheHoleValue, mode); |
| } |
| |
| Node* first_from_element_offset = |
| ElementOffsetFromIndex(first_element, from_kind, mode, 0); |
| Node* limit_offset = IntPtrAdd(first_from_element_offset, |
| IntPtrConstant(first_element_offset)); |
| VARIABLE( |
| var_from_offset, MachineType::PointerRepresentation(), |
| ElementOffsetFromIndex(IntPtrOrSmiAdd(first_element, element_count, mode), |
| from_kind, mode, first_element_offset)); |
| // This second variable is used only when the element sizes of source and |
| // destination arrays do not match. |
| VARIABLE(var_to_offset, MachineType::PointerRepresentation()); |
| if (element_offset_matches) { |
| var_to_offset.Bind(var_from_offset.value()); |
| } else { |
| var_to_offset.Bind(ElementOffsetFromIndex(element_count, to_kind, mode, |
| first_element_offset)); |
| } |
| |
| Variable* vars[] = {&var_from_offset, &var_to_offset, var_holes_converted}; |
| int num_vars = |
| var_holes_converted != nullptr ? arraysize(vars) : arraysize(vars) - 1; |
| Label decrement(this, num_vars, vars); |
| |
| Node* to_array_adjusted = |
| element_offset_matches |
| ? IntPtrSub(BitcastTaggedToWord(to_array), first_from_element_offset) |
| : to_array; |
| |
| Branch(WordEqual(var_from_offset.value(), limit_offset), &done, &decrement); |
| |
| BIND(&decrement); |
| { |
| Node* from_offset = IntPtrSub( |
| var_from_offset.value(), |
| IntPtrConstant(from_double_elements ? kDoubleSize : kTaggedSize)); |
| var_from_offset.Bind(from_offset); |
| |
| Node* to_offset; |
| if (element_offset_matches) { |
| to_offset = from_offset; |
| } else { |
| to_offset = IntPtrSub( |
| var_to_offset.value(), |
| IntPtrConstant(to_double_elements ? kDoubleSize : kTaggedSize)); |
| var_to_offset.Bind(to_offset); |
| } |
| |
| Label next_iter(this), store_double_hole(this), signal_hole(this); |
| Label* if_hole; |
| if (convert_holes == HoleConversionMode::kConvertToUndefined) { |
| // The target elements array is already preinitialized with undefined |
| // so we only need to signal that a hole was found and continue the loop. |
| if_hole = &signal_hole; |
| } else if (doubles_to_objects_conversion) { |
| // The target elements array is already preinitialized with holes, so we |
| // can just proceed with the next iteration. |
| if_hole = &next_iter; |
| } else if (IsDoubleElementsKind(to_kind)) { |
| if_hole = &store_double_hole; |
| } else { |
| // In all the other cases don't check for holes and copy the data as is. |
| if_hole = nullptr; |
| } |
| |
| Node* value = LoadElementAndPrepareForStore( |
| from_array, var_from_offset.value(), from_kind, to_kind, if_hole); |
| |
| if (needs_write_barrier) { |
| CHECK_EQ(to_array, to_array_adjusted); |
| Store(to_array_adjusted, to_offset, value); |
| } else if (to_double_elements) { |
| StoreNoWriteBarrier(MachineRepresentation::kFloat64, to_array_adjusted, |
| to_offset, value); |
| } else { |
| StoreNoWriteBarrier(MachineRepresentation::kTagged, to_array_adjusted, |
| to_offset, value); |
| } |
| Goto(&next_iter); |
| |
| if (if_hole == &store_double_hole) { |
| BIND(&store_double_hole); |
| // Don't use doubles to store the hole double, since manipulating the |
| // signaling NaN used for the hole in C++, e.g. with bit_cast, will |
| // change its value on ia32 (the x87 stack is used to return values |
| // and stores to the stack silently clear the signalling bit). |
| // |
| // TODO(danno): When we have a Float32/Float64 wrapper class that |
| // preserves double bits during manipulation, remove this code/change |
| // this to an indexed Float64 store. |
| if (Is64()) { |
| StoreNoWriteBarrier(MachineRepresentation::kWord64, to_array_adjusted, |
| to_offset, double_hole); |
| } else { |
| StoreNoWriteBarrier(MachineRepresentation::kWord32, to_array_adjusted, |
| to_offset, double_hole); |
| StoreNoWriteBarrier(MachineRepresentation::kWord32, to_array_adjusted, |
| IntPtrAdd(to_offset, IntPtrConstant(kInt32Size)), |
| double_hole); |
| } |
| Goto(&next_iter); |
| } else if (if_hole == &signal_hole) { |
| // This case happens only when IsObjectElementsKind(to_kind). |
| BIND(&signal_hole); |
| if (var_holes_converted != nullptr) { |
| *var_holes_converted = Int32TrueConstant(); |
| } |
| Goto(&next_iter); |
| } |
| |
| BIND(&next_iter); |
| Node* compare = WordNotEqual(from_offset, limit_offset); |
| Branch(compare, &decrement, &done); |
| } |
| |
| BIND(&done); |
| Comment("] CopyFixedArrayElements"); |
| } |
| |
| TNode<FixedArray> CodeStubAssembler::HeapObjectToFixedArray( |
| TNode<HeapObject> base, Label* cast_fail) { |
| Label fixed_array(this); |
| TNode<Map> map = LoadMap(base); |
| GotoIf(WordEqual(map, LoadRoot(RootIndex::kFixedArrayMap)), &fixed_array); |
| GotoIf(WordNotEqual(map, LoadRoot(RootIndex::kFixedCOWArrayMap)), cast_fail); |
| Goto(&fixed_array); |
| BIND(&fixed_array); |
| return UncheckedCast<FixedArray>(base); |
| } |
| |
| void CodeStubAssembler::CopyPropertyArrayValues(Node* from_array, |
| Node* to_array, |
| Node* property_count, |
| WriteBarrierMode barrier_mode, |
| ParameterMode mode, |
| DestroySource destroy_source) { |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(property_count, mode)); |
| CSA_SLOW_ASSERT(this, Word32Or(IsPropertyArray(from_array), |
| IsEmptyFixedArray(from_array))); |
| CSA_SLOW_ASSERT(this, IsPropertyArray(to_array)); |
| Comment("[ CopyPropertyArrayValues"); |
| |
| bool needs_write_barrier = barrier_mode == UPDATE_WRITE_BARRIER; |
| |
| if (destroy_source == DestroySource::kNo) { |
| // PropertyArray may contain MutableHeapNumbers, which will be cloned on the |
| // heap, requiring a write barrier. |
| needs_write_barrier = true; |
| } |
| |
| Node* start = IntPtrOrSmiConstant(0, mode); |
| ElementsKind kind = PACKED_ELEMENTS; |
| BuildFastFixedArrayForEach( |
| from_array, kind, start, property_count, |
| [this, to_array, needs_write_barrier, destroy_source](Node* array, |
| Node* offset) { |
| Node* value = Load(MachineType::AnyTagged(), array, offset); |
| |
| if (destroy_source == DestroySource::kNo) { |
| value = CloneIfMutablePrimitive(CAST(value)); |
| } |
| |
| if (needs_write_barrier) { |
| Store(to_array, offset, value); |
| } else { |
| StoreNoWriteBarrier(MachineRepresentation::kTagged, to_array, offset, |
| value); |
| } |
| }, |
| mode); |
| |
| #ifdef DEBUG |
| // Zap {from_array} if the copying above has made it invalid. |
| if (destroy_source == DestroySource::kYes) { |
| Label did_zap(this); |
| GotoIf(IsEmptyFixedArray(from_array), &did_zap); |
| FillPropertyArrayWithUndefined(from_array, start, property_count, mode); |
| |
| Goto(&did_zap); |
| BIND(&did_zap); |
| } |
| #endif |
| Comment("] CopyPropertyArrayValues"); |
| } |
| |
| void CodeStubAssembler::CopyStringCharacters(Node* from_string, Node* to_string, |
| TNode<IntPtrT> from_index, |
| TNode<IntPtrT> to_index, |
| TNode<IntPtrT> character_count, |
| String::Encoding from_encoding, |
| String::Encoding to_encoding) { |
| // Cannot assert IsString(from_string) and IsString(to_string) here because |
| // CSA::SubString can pass in faked sequential strings when handling external |
| // subject strings. |
| bool from_one_byte = from_encoding == String::ONE_BYTE_ENCODING; |
| bool to_one_byte = to_encoding == String::ONE_BYTE_ENCODING; |
| DCHECK_IMPLIES(to_one_byte, from_one_byte); |
| Comment("CopyStringCharacters ", |
| from_one_byte ? "ONE_BYTE_ENCODING" : "TWO_BYTE_ENCODING", " -> ", |
| to_one_byte ? "ONE_BYTE_ENCODING" : "TWO_BYTE_ENCODING"); |
| |
| ElementsKind from_kind = from_one_byte ? UINT8_ELEMENTS : UINT16_ELEMENTS; |
| ElementsKind to_kind = to_one_byte ? UINT8_ELEMENTS : UINT16_ELEMENTS; |
| STATIC_ASSERT(SeqOneByteString::kHeaderSize == SeqTwoByteString::kHeaderSize); |
| int header_size = SeqOneByteString::kHeaderSize - kHeapObjectTag; |
| Node* from_offset = ElementOffsetFromIndex(from_index, from_kind, |
| INTPTR_PARAMETERS, header_size); |
| Node* to_offset = |
| ElementOffsetFromIndex(to_index, to_kind, INTPTR_PARAMETERS, header_size); |
| Node* byte_count = |
| ElementOffsetFromIndex(character_count, from_kind, INTPTR_PARAMETERS); |
| Node* limit_offset = IntPtrAdd(from_offset, byte_count); |
| |
| // Prepare the fast loop |
| MachineType type = |
| from_one_byte ? MachineType::Uint8() : MachineType::Uint16(); |
| MachineRepresentation rep = to_one_byte ? MachineRepresentation::kWord8 |
| : MachineRepresentation::kWord16; |
| int from_increment = 1 << ElementsKindToShiftSize(from_kind); |
| int to_increment = 1 << ElementsKindToShiftSize(to_kind); |
| |
| VARIABLE(current_to_offset, MachineType::PointerRepresentation(), to_offset); |
| VariableList vars({¤t_to_offset}, zone()); |
| int to_index_constant = 0, from_index_constant = 0; |
| bool index_same = (from_encoding == to_encoding) && |
| (from_index == to_index || |
| (ToInt32Constant(from_index, from_index_constant) && |
| ToInt32Constant(to_index, to_index_constant) && |
| from_index_constant == to_index_constant)); |
| BuildFastLoop(vars, from_offset, limit_offset, |
| [this, from_string, to_string, ¤t_to_offset, to_increment, |
| type, rep, index_same](Node* offset) { |
| Node* value = Load(type, from_string, offset); |
| StoreNoWriteBarrier( |
| rep, to_string, |
| index_same ? offset : current_to_offset.value(), value); |
| if (!index_same) { |
| Increment(¤t_to_offset, to_increment); |
| } |
| }, |
| from_increment, INTPTR_PARAMETERS, IndexAdvanceMode::kPost); |
| } |
| |
| Node* CodeStubAssembler::LoadElementAndPrepareForStore(Node* array, |
| Node* offset, |
| ElementsKind from_kind, |
| ElementsKind to_kind, |
| Label* if_hole) { |
| CSA_ASSERT(this, IsFixedArrayWithKind(array, from_kind)); |
| if (IsDoubleElementsKind(from_kind)) { |
| Node* value = |
| LoadDoubleWithHoleCheck(array, offset, if_hole, MachineType::Float64()); |
| if (!IsDoubleElementsKind(to_kind)) { |
| value = AllocateHeapNumberWithValue(value); |
| } |
| return value; |
| |
| } else { |
| Node* value = Load(MachineType::AnyTagged(), array, offset); |
| if (if_hole) { |
| GotoIf(WordEqual(value, TheHoleConstant()), if_hole); |
| } |
| if (IsDoubleElementsKind(to_kind)) { |
| if (IsSmiElementsKind(from_kind)) { |
| value = SmiToFloat64(value); |
| } else { |
| value = LoadHeapNumberValue(value); |
| } |
| } |
| return value; |
| } |
| } |
| |
| Node* CodeStubAssembler::CalculateNewElementsCapacity(Node* old_capacity, |
| ParameterMode mode) { |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(old_capacity, mode)); |
| Node* half_old_capacity = WordOrSmiShr(old_capacity, 1, mode); |
| Node* new_capacity = IntPtrOrSmiAdd(half_old_capacity, old_capacity, mode); |
| Node* padding = |
| IntPtrOrSmiConstant(JSObject::kMinAddedElementsCapacity, mode); |
| return IntPtrOrSmiAdd(new_capacity, padding, mode); |
| } |
| |
| Node* CodeStubAssembler::TryGrowElementsCapacity(Node* object, Node* elements, |
| ElementsKind kind, Node* key, |
| Label* bailout) { |
| CSA_SLOW_ASSERT(this, TaggedIsNotSmi(object)); |
| CSA_SLOW_ASSERT(this, IsFixedArrayWithKindOrEmpty(elements, kind)); |
| CSA_SLOW_ASSERT(this, TaggedIsSmi(key)); |
| Node* capacity = LoadFixedArrayBaseLength(elements); |
| |
| ParameterMode mode = OptimalParameterMode(); |
| capacity = TaggedToParameter(capacity, mode); |
| key = TaggedToParameter(key, mode); |
| |
| return TryGrowElementsCapacity(object, elements, kind, key, capacity, mode, |
| bailout); |
| } |
| |
| Node* CodeStubAssembler::TryGrowElementsCapacity(Node* object, Node* elements, |
| ElementsKind kind, Node* key, |
| Node* capacity, |
| ParameterMode mode, |
| Label* bailout) { |
| Comment("TryGrowElementsCapacity"); |
| CSA_SLOW_ASSERT(this, TaggedIsNotSmi(object)); |
| CSA_SLOW_ASSERT(this, IsFixedArrayWithKindOrEmpty(elements, kind)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(capacity, mode)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(key, mode)); |
| |
| // If the gap growth is too big, fall back to the runtime. |
| Node* max_gap = IntPtrOrSmiConstant(JSObject::kMaxGap, mode); |
| Node* max_capacity = IntPtrOrSmiAdd(capacity, max_gap, mode); |
| GotoIf(UintPtrOrSmiGreaterThanOrEqual(key, max_capacity, mode), bailout); |
| |
| // Calculate the capacity of the new backing store. |
| Node* new_capacity = CalculateNewElementsCapacity( |
| IntPtrOrSmiAdd(key, IntPtrOrSmiConstant(1, mode), mode), mode); |
| return GrowElementsCapacity(object, elements, kind, kind, capacity, |
| new_capacity, mode, bailout); |
| } |
| |
| Node* CodeStubAssembler::GrowElementsCapacity( |
| Node* object, Node* elements, ElementsKind from_kind, ElementsKind to_kind, |
| Node* capacity, Node* new_capacity, ParameterMode mode, Label* bailout) { |
| Comment("[ GrowElementsCapacity"); |
| CSA_SLOW_ASSERT(this, TaggedIsNotSmi(object)); |
| CSA_SLOW_ASSERT(this, IsFixedArrayWithKindOrEmpty(elements, from_kind)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(capacity, mode)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(new_capacity, mode)); |
| |
| // If size of the allocation for the new capacity doesn't fit in a page |
| // that we can bump-pointer allocate from, fall back to the runtime. |
| int max_size = FixedArrayBase::GetMaxLengthForNewSpaceAllocation(to_kind); |
| GotoIf(UintPtrOrSmiGreaterThanOrEqual( |
| new_capacity, IntPtrOrSmiConstant(max_size, mode), mode), |
| bailout); |
| |
| // Allocate the new backing store. |
| Node* new_elements = AllocateFixedArray(to_kind, new_capacity, mode); |
| |
| // Copy the elements from the old elements store to the new. |
| // The size-check above guarantees that the |new_elements| is allocated |
| // in new space so we can skip the write barrier. |
| CopyFixedArrayElements(from_kind, elements, to_kind, new_elements, capacity, |
| new_capacity, SKIP_WRITE_BARRIER, mode); |
| |
| StoreObjectField(object, JSObject::kElementsOffset, new_elements); |
| Comment("] GrowElementsCapacity"); |
| return new_elements; |
| } |
| |
| void CodeStubAssembler::InitializeAllocationMemento(Node* base, |
| Node* base_allocation_size, |
| Node* allocation_site) { |
| Comment("[Initialize AllocationMemento"); |
| TNode<Object> memento = |
| InnerAllocate(CAST(base), UncheckedCast<IntPtrT>(base_allocation_size)); |
| StoreMapNoWriteBarrier(memento, RootIndex::kAllocationMementoMap); |
| StoreObjectFieldNoWriteBarrier( |
| memento, AllocationMemento::kAllocationSiteOffset, allocation_site); |
| if (FLAG_allocation_site_pretenuring) { |
| TNode<Int32T> count = UncheckedCast<Int32T>(LoadObjectField( |
| allocation_site, AllocationSite::kPretenureCreateCountOffset, |
| MachineType::Int32())); |
| |
| TNode<Int32T> incremented_count = Int32Add(count, Int32Constant(1)); |
| StoreObjectFieldNoWriteBarrier( |
| allocation_site, AllocationSite::kPretenureCreateCountOffset, |
| incremented_count, MachineRepresentation::kWord32); |
| } |
| Comment("]"); |
| } |
| |
| Node* CodeStubAssembler::TryTaggedToFloat64(Node* value, |
| Label* if_valueisnotnumber) { |
| Label out(this); |
| VARIABLE(var_result, MachineRepresentation::kFloat64); |
| |
| // Check if the {value} is a Smi or a HeapObject. |
| Label if_valueissmi(this), if_valueisnotsmi(this); |
| Branch(TaggedIsSmi(value), &if_valueissmi, &if_valueisnotsmi); |
| |
| BIND(&if_valueissmi); |
| { |
| // Convert the Smi {value}. |
| var_result.Bind(SmiToFloat64(value)); |
| Goto(&out); |
| } |
| |
| BIND(&if_valueisnotsmi); |
| { |
| // Check if {value} is a HeapNumber. |
| Label if_valueisheapnumber(this); |
| Branch(IsHeapNumber(value), &if_valueisheapnumber, if_valueisnotnumber); |
| |
| BIND(&if_valueisheapnumber); |
| { |
| // Load the floating point value. |
| var_result.Bind(LoadHeapNumberValue(value)); |
| Goto(&out); |
| } |
| } |
| BIND(&out); |
| return var_result.value(); |
| } |
| |
| Node* CodeStubAssembler::TruncateTaggedToFloat64(Node* context, Node* value) { |
| // We might need to loop once due to ToNumber conversion. |
| VARIABLE(var_value, MachineRepresentation::kTagged); |
| VARIABLE(var_result, MachineRepresentation::kFloat64); |
| Label loop(this, &var_value), done_loop(this, &var_result); |
| var_value.Bind(value); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| Label if_valueisnotnumber(this, Label::kDeferred); |
| |
| // Load the current {value}. |
| value = var_value.value(); |
| |
| // Convert {value} to Float64 if it is a number and convert it to a number |
| // otherwise. |
| Node* const result = TryTaggedToFloat64(value, &if_valueisnotnumber); |
| var_result.Bind(result); |
| Goto(&done_loop); |
| |
| BIND(&if_valueisnotnumber); |
| { |
| // Convert the {value} to a Number first. |
| var_value.Bind(CallBuiltin(Builtins::kNonNumberToNumber, context, value)); |
| Goto(&loop); |
| } |
| } |
| BIND(&done_loop); |
| return var_result.value(); |
| } |
| |
| Node* CodeStubAssembler::TruncateTaggedToWord32(Node* context, Node* value) { |
| VARIABLE(var_result, MachineRepresentation::kWord32); |
| Label done(this); |
| TaggedToWord32OrBigIntImpl<Object::Conversion::kToNumber>(context, value, |
| &done, &var_result); |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| // Truncate {value} to word32 and jump to {if_number} if it is a Number, |
| // or find that it is a BigInt and jump to {if_bigint}. |
| void CodeStubAssembler::TaggedToWord32OrBigInt(Node* context, Node* value, |
| Label* if_number, |
| Variable* var_word32, |
| Label* if_bigint, |
| Variable* var_bigint) { |
| TaggedToWord32OrBigIntImpl<Object::Conversion::kToNumeric>( |
| context, value, if_number, var_word32, if_bigint, var_bigint); |
| } |
| |
| // Truncate {value} to word32 and jump to {if_number} if it is a Number, |
| // or find that it is a BigInt and jump to {if_bigint}. In either case, |
| // store the type feedback in {var_feedback}. |
| void CodeStubAssembler::TaggedToWord32OrBigIntWithFeedback( |
| Node* context, Node* value, Label* if_number, Variable* var_word32, |
| Label* if_bigint, Variable* var_bigint, Variable* var_feedback) { |
| TaggedToWord32OrBigIntImpl<Object::Conversion::kToNumeric>( |
| context, value, if_number, var_word32, if_bigint, var_bigint, |
| var_feedback); |
| } |
| |
| template <Object::Conversion conversion> |
| void CodeStubAssembler::TaggedToWord32OrBigIntImpl( |
| Node* context, Node* value, Label* if_number, Variable* var_word32, |
| Label* if_bigint, Variable* var_bigint, Variable* var_feedback) { |
| DCHECK(var_word32->rep() == MachineRepresentation::kWord32); |
| DCHECK(var_bigint == nullptr || |
| var_bigint->rep() == MachineRepresentation::kTagged); |
| DCHECK(var_feedback == nullptr || |
| var_feedback->rep() == MachineRepresentation::kTaggedSigned); |
| |
| // We might need to loop after conversion. |
| VARIABLE(var_value, MachineRepresentation::kTagged, value); |
| OverwriteFeedback(var_feedback, BinaryOperationFeedback::kNone); |
| Variable* loop_vars[] = {&var_value, var_feedback}; |
| int num_vars = |
| var_feedback != nullptr ? arraysize(loop_vars) : arraysize(loop_vars) - 1; |
| Label loop(this, num_vars, loop_vars); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| value = var_value.value(); |
| Label not_smi(this), is_heap_number(this), is_oddball(this), |
| is_bigint(this); |
| GotoIf(TaggedIsNotSmi(value), ¬_smi); |
| |
| // {value} is a Smi. |
| var_word32->Bind(SmiToInt32(value)); |
| CombineFeedback(var_feedback, BinaryOperationFeedback::kSignedSmall); |
| Goto(if_number); |
| |
| BIND(¬_smi); |
| Node* map = LoadMap(value); |
| GotoIf(IsHeapNumberMap(map), &is_heap_number); |
| Node* instance_type = LoadMapInstanceType(map); |
| if (conversion == Object::Conversion::kToNumeric) { |
| GotoIf(IsBigIntInstanceType(instance_type), &is_bigint); |
| } |
| |
| // Not HeapNumber (or BigInt if conversion == kToNumeric). |
| { |
| if (var_feedback != nullptr) { |
| // We do not require an Or with earlier feedback here because once we |
| // convert the value to a Numeric, we cannot reach this path. We can |
| // only reach this path on the first pass when the feedback is kNone. |
| CSA_ASSERT(this, SmiEqual(CAST(var_feedback->value()), |
| SmiConstant(BinaryOperationFeedback::kNone))); |
| } |
| GotoIf(InstanceTypeEqual(instance_type, ODDBALL_TYPE), &is_oddball); |
| // Not an oddball either -> convert. |
| auto builtin = conversion == Object::Conversion::kToNumeric |
| ? Builtins::kNonNumberToNumeric |
| : Builtins::kNonNumberToNumber; |
| var_value.Bind(CallBuiltin(builtin, context, value)); |
| OverwriteFeedback(var_feedback, BinaryOperationFeedback::kAny); |
| Goto(&loop); |
| |
| BIND(&is_oddball); |
| var_value.Bind(LoadObjectField(value, Oddball::kToNumberOffset)); |
| OverwriteFeedback(var_feedback, |
| BinaryOperationFeedback::kNumberOrOddball); |
| Goto(&loop); |
| } |
| |
| BIND(&is_heap_number); |
| var_word32->Bind(TruncateHeapNumberValueToWord32(value)); |
| CombineFeedback(var_feedback, BinaryOperationFeedback::kNumber); |
| Goto(if_number); |
| |
| if (conversion == Object::Conversion::kToNumeric) { |
| BIND(&is_bigint); |
| var_bigint->Bind(value); |
| CombineFeedback(var_feedback, BinaryOperationFeedback::kBigInt); |
| Goto(if_bigint); |
| } |
| } |
| } |
| |
| Node* CodeStubAssembler::TruncateHeapNumberValueToWord32(Node* object) { |
| Node* value = LoadHeapNumberValue(object); |
| return TruncateFloat64ToWord32(value); |
| } |
| |
| void CodeStubAssembler::TryHeapNumberToSmi(TNode<HeapNumber> number, |
| TVariable<Smi>& var_result_smi, |
| Label* if_smi) { |
| TNode<Float64T> value = LoadHeapNumberValue(number); |
| TryFloat64ToSmi(value, var_result_smi, if_smi); |
| } |
| |
| void CodeStubAssembler::TryFloat64ToSmi(TNode<Float64T> value, |
| TVariable<Smi>& var_result_smi, |
| Label* if_smi) { |
| TNode<Int32T> value32 = RoundFloat64ToInt32(value); |
| TNode<Float64T> value64 = ChangeInt32ToFloat64(value32); |
| |
| Label if_int32(this), if_heap_number(this, Label::kDeferred); |
| |
| GotoIfNot(Float64Equal(value, value64), &if_heap_number); |
| GotoIfNot(Word32Equal(value32, Int32Constant(0)), &if_int32); |
| Branch(Int32LessThan(UncheckedCast<Int32T>(Float64ExtractHighWord32(value)), |
| Int32Constant(0)), |
| &if_heap_number, &if_int32); |
| |
| TVARIABLE(Number, var_result); |
| BIND(&if_int32); |
| { |
| if (SmiValuesAre32Bits()) { |
| var_result_smi = SmiTag(ChangeInt32ToIntPtr(value32)); |
| } else { |
| DCHECK(SmiValuesAre31Bits()); |
| TNode<PairT<Int32T, BoolT>> pair = Int32AddWithOverflow(value32, value32); |
| TNode<BoolT> overflow = Projection<1>(pair); |
| GotoIf(overflow, &if_heap_number); |
| var_result_smi = |
| BitcastWordToTaggedSigned(ChangeInt32ToIntPtr(Projection<0>(pair))); |
| } |
| Goto(if_smi); |
| } |
| BIND(&if_heap_number); |
| } |
| |
| TNode<Number> CodeStubAssembler::ChangeFloat64ToTagged( |
| SloppyTNode<Float64T> value) { |
| Label if_smi(this), done(this); |
| TVARIABLE(Smi, var_smi_result); |
| TVARIABLE(Number, var_result); |
| TryFloat64ToSmi(value, var_smi_result, &if_smi); |
| |
| var_result = AllocateHeapNumberWithValue(value); |
| Goto(&done); |
| |
| BIND(&if_smi); |
| { |
| var_result = var_smi_result.value(); |
| Goto(&done); |
| } |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::ChangeInt32ToTagged( |
| SloppyTNode<Int32T> value) { |
| if (SmiValuesAre32Bits()) { |
| return SmiTag(ChangeInt32ToIntPtr(value)); |
| } |
| DCHECK(SmiValuesAre31Bits()); |
| TVARIABLE(Number, var_result); |
| TNode<PairT<Int32T, BoolT>> pair = Int32AddWithOverflow(value, value); |
| TNode<BoolT> overflow = Projection<1>(pair); |
| Label if_overflow(this, Label::kDeferred), if_notoverflow(this), |
| if_join(this); |
| Branch(overflow, &if_overflow, &if_notoverflow); |
| BIND(&if_overflow); |
| { |
| TNode<Float64T> value64 = ChangeInt32ToFloat64(value); |
| TNode<HeapNumber> result = AllocateHeapNumberWithValue(value64); |
| var_result = result; |
| Goto(&if_join); |
| } |
| BIND(&if_notoverflow); |
| { |
| TNode<IntPtrT> almost_tagged_value = |
| ChangeInt32ToIntPtr(Projection<0>(pair)); |
| TNode<Smi> result = BitcastWordToTaggedSigned(almost_tagged_value); |
| var_result = result; |
| Goto(&if_join); |
| } |
| BIND(&if_join); |
| return var_result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::ChangeUint32ToTagged( |
| SloppyTNode<Uint32T> value) { |
| Label if_overflow(this, Label::kDeferred), if_not_overflow(this), |
| if_join(this); |
| TVARIABLE(Number, var_result); |
| // If {value} > 2^31 - 1, we need to store it in a HeapNumber. |
| Branch(Uint32LessThan(Uint32Constant(Smi::kMaxValue), value), &if_overflow, |
| &if_not_overflow); |
| |
| BIND(&if_not_overflow); |
| { |
| // The {value} is definitely in valid Smi range. |
| var_result = SmiTag(Signed(ChangeUint32ToWord(value))); |
| } |
| Goto(&if_join); |
| |
| BIND(&if_overflow); |
| { |
| TNode<Float64T> float64_value = ChangeUint32ToFloat64(value); |
| var_result = AllocateHeapNumberWithValue(float64_value); |
| } |
| Goto(&if_join); |
| |
| BIND(&if_join); |
| return var_result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::ChangeUintPtrToTagged(TNode<UintPtrT> value) { |
| Label if_overflow(this, Label::kDeferred), if_not_overflow(this), |
| if_join(this); |
| TVARIABLE(Number, var_result); |
| // If {value} > 2^31 - 1, we need to store it in a HeapNumber. |
| Branch(UintPtrLessThan(UintPtrConstant(Smi::kMaxValue), value), &if_overflow, |
| &if_not_overflow); |
| |
| BIND(&if_not_overflow); |
| { |
| // The {value} is definitely in valid Smi range. |
| var_result = SmiTag(Signed(value)); |
| } |
| Goto(&if_join); |
| |
| BIND(&if_overflow); |
| { |
| TNode<Float64T> float64_value = ChangeUintPtrToFloat64(value); |
| var_result = AllocateHeapNumberWithValue(float64_value); |
| } |
| Goto(&if_join); |
| |
| BIND(&if_join); |
| return var_result.value(); |
| } |
| |
| TNode<String> CodeStubAssembler::ToThisString(Node* context, Node* value, |
| char const* method_name) { |
| VARIABLE(var_value, MachineRepresentation::kTagged, value); |
| |
| // Check if the {value} is a Smi or a HeapObject. |
| Label if_valueissmi(this, Label::kDeferred), if_valueisnotsmi(this), |
| if_valueisstring(this); |
| Branch(TaggedIsSmi(value), &if_valueissmi, &if_valueisnotsmi); |
| BIND(&if_valueisnotsmi); |
| { |
| // Load the instance type of the {value}. |
| Node* value_instance_type = LoadInstanceType(value); |
| |
| // Check if the {value} is already String. |
| Label if_valueisnotstring(this, Label::kDeferred); |
| Branch(IsStringInstanceType(value_instance_type), &if_valueisstring, |
| &if_valueisnotstring); |
| BIND(&if_valueisnotstring); |
| { |
| // Check if the {value} is null. |
| Label if_valueisnullorundefined(this, Label::kDeferred); |
| GotoIf(IsNullOrUndefined(value), &if_valueisnullorundefined); |
| // Convert the {value} to a String. |
| var_value.Bind(CallBuiltin(Builtins::kToString, context, value)); |
| Goto(&if_valueisstring); |
| |
| BIND(&if_valueisnullorundefined); |
| { |
| // The {value} is either null or undefined. |
| ThrowTypeError(context, MessageTemplate::kCalledOnNullOrUndefined, |
| method_name); |
| } |
| } |
| } |
| BIND(&if_valueissmi); |
| { |
| // The {value} is a Smi, convert it to a String. |
| var_value.Bind(CallBuiltin(Builtins::kNumberToString, context, value)); |
| Goto(&if_valueisstring); |
| } |
| BIND(&if_valueisstring); |
| return CAST(var_value.value()); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::ChangeNumberToUint32(TNode<Number> value) { |
| TVARIABLE(Uint32T, var_result); |
| Label if_smi(this), if_heapnumber(this, Label::kDeferred), done(this); |
| Branch(TaggedIsSmi(value), &if_smi, &if_heapnumber); |
| BIND(&if_smi); |
| { |
| var_result = Unsigned(SmiToInt32(CAST(value))); |
| Goto(&done); |
| } |
| BIND(&if_heapnumber); |
| { |
| var_result = ChangeFloat64ToUint32(LoadHeapNumberValue(CAST(value))); |
| Goto(&done); |
| } |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| TNode<Float64T> CodeStubAssembler::ChangeNumberToFloat64( |
| SloppyTNode<Number> value) { |
| // TODO(tebbi): Remove assert once argument is TNode instead of SloppyTNode. |
| CSA_SLOW_ASSERT(this, IsNumber(value)); |
| TVARIABLE(Float64T, result); |
| Label smi(this); |
| Label done(this, &result); |
| GotoIf(TaggedIsSmi(value), &smi); |
| result = LoadHeapNumberValue(CAST(value)); |
| Goto(&done); |
| |
| BIND(&smi); |
| { |
| result = SmiToFloat64(CAST(value)); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<UintPtrT> CodeStubAssembler::TryNumberToUintPtr(TNode<Number> value, |
| Label* if_negative) { |
| TVARIABLE(UintPtrT, result); |
| Label done(this, &result); |
| Branch(TaggedIsSmi(value), |
| [&] { |
| TNode<Smi> value_smi = CAST(value); |
| if (if_negative == nullptr) { |
| CSA_SLOW_ASSERT(this, SmiLessThan(SmiConstant(-1), value_smi)); |
| } else { |
| GotoIfNot(TaggedIsPositiveSmi(value), if_negative); |
| } |
| result = UncheckedCast<UintPtrT>(SmiToIntPtr(value_smi)); |
| Goto(&done); |
| }, |
| [&] { |
| TNode<HeapNumber> value_hn = CAST(value); |
| TNode<Float64T> value = LoadHeapNumberValue(value_hn); |
| if (if_negative != nullptr) { |
| GotoIf(Float64LessThan(value, Float64Constant(0.0)), if_negative); |
| } |
| result = ChangeFloat64ToUintPtr(value); |
| Goto(&done); |
| }); |
| |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<WordT> CodeStubAssembler::TimesSystemPointerSize( |
| SloppyTNode<WordT> value) { |
| return WordShl(value, kSystemPointerSizeLog2); |
| } |
| |
| TNode<WordT> CodeStubAssembler::TimesTaggedSize(SloppyTNode<WordT> value) { |
| return WordShl(value, kTaggedSizeLog2); |
| } |
| |
| TNode<WordT> CodeStubAssembler::TimesDoubleSize(SloppyTNode<WordT> value) { |
| return WordShl(value, kDoubleSizeLog2); |
| } |
| |
| Node* CodeStubAssembler::ToThisValue(Node* context, Node* value, |
| PrimitiveType primitive_type, |
| char const* method_name) { |
| // We might need to loop once due to JSValue unboxing. |
| VARIABLE(var_value, MachineRepresentation::kTagged, value); |
| Label loop(this, &var_value), done_loop(this), |
| done_throw(this, Label::kDeferred); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| // Load the current {value}. |
| value = var_value.value(); |
| |
| // Check if the {value} is a Smi or a HeapObject. |
| GotoIf(TaggedIsSmi(value), (primitive_type == PrimitiveType::kNumber) |
| ? &done_loop |
| : &done_throw); |
| |
| // Load the map of the {value}. |
| Node* value_map = LoadMap(value); |
| |
| // Load the instance type of the {value}. |
| Node* value_instance_type = LoadMapInstanceType(value_map); |
| |
| // Check if {value} is a JSValue. |
| Label if_valueisvalue(this, Label::kDeferred), if_valueisnotvalue(this); |
| Branch(InstanceTypeEqual(value_instance_type, JS_VALUE_TYPE), |
| &if_valueisvalue, &if_valueisnotvalue); |
| |
| BIND(&if_valueisvalue); |
| { |
| // Load the actual value from the {value}. |
| var_value.Bind(LoadObjectField(value, JSValue::kValueOffset)); |
| Goto(&loop); |
| } |
| |
| BIND(&if_valueisnotvalue); |
| { |
| switch (primitive_type) { |
| case PrimitiveType::kBoolean: |
| GotoIf(WordEqual(value_map, BooleanMapConstant()), &done_loop); |
| break; |
| case PrimitiveType::kNumber: |
| GotoIf(WordEqual(value_map, HeapNumberMapConstant()), &done_loop); |
| break; |
| case PrimitiveType::kString: |
| GotoIf(IsStringInstanceType(value_instance_type), &done_loop); |
| break; |
| case PrimitiveType::kSymbol: |
| GotoIf(WordEqual(value_map, SymbolMapConstant()), &done_loop); |
| break; |
| } |
| Goto(&done_throw); |
| } |
| } |
| |
| BIND(&done_throw); |
| { |
| const char* primitive_name = nullptr; |
| switch (primitive_type) { |
| case PrimitiveType::kBoolean: |
| primitive_name = "Boolean"; |
| break; |
| case PrimitiveType::kNumber: |
| primitive_name = "Number"; |
| break; |
| case PrimitiveType::kString: |
| primitive_name = "String"; |
| break; |
| case PrimitiveType::kSymbol: |
| primitive_name = "Symbol"; |
| break; |
| } |
| CHECK_NOT_NULL(primitive_name); |
| |
| // The {value} is not a compatible receiver for this method. |
| ThrowTypeError(context, MessageTemplate::kNotGeneric, method_name, |
| primitive_name); |
| } |
| |
| BIND(&done_loop); |
| return var_value.value(); |
| } |
| |
| Node* CodeStubAssembler::ThrowIfNotInstanceType(Node* context, Node* value, |
| InstanceType instance_type, |
| char const* method_name) { |
| Label out(this), throw_exception(this, Label::kDeferred); |
| VARIABLE(var_value_map, MachineRepresentation::kTagged); |
| |
| GotoIf(TaggedIsSmi(value), &throw_exception); |
| |
| // Load the instance type of the {value}. |
| var_value_map.Bind(LoadMap(value)); |
| Node* const value_instance_type = LoadMapInstanceType(var_value_map.value()); |
| |
| Branch(Word32Equal(value_instance_type, Int32Constant(instance_type)), &out, |
| &throw_exception); |
| |
| // The {value} is not a compatible receiver for this method. |
| BIND(&throw_exception); |
| ThrowTypeError(context, MessageTemplate::kIncompatibleMethodReceiver, |
| StringConstant(method_name), value); |
| |
| BIND(&out); |
| return var_value_map.value(); |
| } |
| |
| Node* CodeStubAssembler::ThrowIfNotJSReceiver(Node* context, Node* value, |
| MessageTemplate msg_template, |
| const char* method_name) { |
| Label out(this), throw_exception(this, Label::kDeferred); |
| VARIABLE(var_value_map, MachineRepresentation::kTagged); |
| |
| GotoIf(TaggedIsSmi(value), &throw_exception); |
| |
| // Load the instance type of the {value}. |
| var_value_map.Bind(LoadMap(value)); |
| Node* const value_instance_type = LoadMapInstanceType(var_value_map.value()); |
| |
| Branch(IsJSReceiverInstanceType(value_instance_type), &out, &throw_exception); |
| |
| // The {value} is not a compatible receiver for this method. |
| BIND(&throw_exception); |
| ThrowTypeError(context, msg_template, method_name); |
| |
| BIND(&out); |
| return var_value_map.value(); |
| } |
| |
| void CodeStubAssembler::ThrowRangeError(Node* context, MessageTemplate message, |
| Node* arg0, Node* arg1, Node* arg2) { |
| Node* template_index = SmiConstant(static_cast<int>(message)); |
| if (arg0 == nullptr) { |
| CallRuntime(Runtime::kThrowRangeError, context, template_index); |
| } else if (arg1 == nullptr) { |
| CallRuntime(Runtime::kThrowRangeError, context, template_index, arg0); |
| } else if (arg2 == nullptr) { |
| CallRuntime(Runtime::kThrowRangeError, context, template_index, arg0, arg1); |
| } else { |
| CallRuntime(Runtime::kThrowRangeError, context, template_index, arg0, arg1, |
| arg2); |
| } |
| Unreachable(); |
| } |
| |
| void CodeStubAssembler::ThrowTypeError(Node* context, MessageTemplate message, |
| char const* arg0, char const* arg1) { |
| Node* arg0_node = nullptr; |
| if (arg0) arg0_node = StringConstant(arg0); |
| Node* arg1_node = nullptr; |
| if (arg1) arg1_node = StringConstant(arg1); |
| ThrowTypeError(context, message, arg0_node, arg1_node); |
| } |
| |
| void CodeStubAssembler::ThrowTypeError(Node* context, MessageTemplate message, |
| Node* arg0, Node* arg1, Node* arg2) { |
| Node* template_index = SmiConstant(static_cast<int>(message)); |
| if (arg0 == nullptr) { |
| CallRuntime(Runtime::kThrowTypeError, context, template_index); |
| } else if (arg1 == nullptr) { |
| CallRuntime(Runtime::kThrowTypeError, context, template_index, arg0); |
| } else if (arg2 == nullptr) { |
| CallRuntime(Runtime::kThrowTypeError, context, template_index, arg0, arg1); |
| } else { |
| CallRuntime(Runtime::kThrowTypeError, context, template_index, arg0, arg1, |
| arg2); |
| } |
| Unreachable(); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::InstanceTypeEqual( |
| SloppyTNode<Int32T> instance_type, int type) { |
| return Word32Equal(instance_type, Int32Constant(type)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsDictionaryMap(SloppyTNode<Map> map) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| Node* bit_field3 = LoadMapBitField3(map); |
| return IsSetWord32<Map::IsDictionaryMapBit>(bit_field3); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsExtensibleMap(SloppyTNode<Map> map) { |
| CSA_ASSERT(this, IsMap(map)); |
| return IsSetWord32<Map::IsExtensibleBit>(LoadMapBitField2(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsExtensibleNonPrototypeMap(TNode<Map> map) { |
| int kMask = Map::IsExtensibleBit::kMask | Map::IsPrototypeMapBit::kMask; |
| int kExpected = Map::IsExtensibleBit::kMask; |
| return Word32Equal(Word32And(LoadMapBitField2(map), Int32Constant(kMask)), |
| Int32Constant(kExpected)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsCallableMap(SloppyTNode<Map> map) { |
| CSA_ASSERT(this, IsMap(map)); |
| return IsSetWord32<Map::IsCallableBit>(LoadMapBitField(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsDeprecatedMap(SloppyTNode<Map> map) { |
| CSA_ASSERT(this, IsMap(map)); |
| return IsSetWord32<Map::IsDeprecatedBit>(LoadMapBitField3(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsUndetectableMap(SloppyTNode<Map> map) { |
| CSA_ASSERT(this, IsMap(map)); |
| return IsSetWord32<Map::IsUndetectableBit>(LoadMapBitField(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNoElementsProtectorCellInvalid() { |
| Node* invalid = SmiConstant(Isolate::kProtectorInvalid); |
| Node* cell = LoadRoot(RootIndex::kNoElementsProtector); |
| Node* cell_value = LoadObjectField(cell, PropertyCell::kValueOffset); |
| return WordEqual(cell_value, invalid); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsArrayIteratorProtectorCellInvalid() { |
| Node* invalid = SmiConstant(Isolate::kProtectorInvalid); |
| Node* cell = LoadRoot(RootIndex::kArrayIteratorProtector); |
| Node* cell_value = LoadObjectField(cell, PropertyCell::kValueOffset); |
| return WordEqual(cell_value, invalid); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsPromiseResolveProtectorCellInvalid() { |
| Node* invalid = SmiConstant(Isolate::kProtectorInvalid); |
| Node* cell = LoadRoot(RootIndex::kPromiseResolveProtector); |
| Node* cell_value = LoadObjectField(cell, Cell::kValueOffset); |
| return WordEqual(cell_value, invalid); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsPromiseThenProtectorCellInvalid() { |
| Node* invalid = SmiConstant(Isolate::kProtectorInvalid); |
| Node* cell = LoadRoot(RootIndex::kPromiseThenProtector); |
| Node* cell_value = LoadObjectField(cell, PropertyCell::kValueOffset); |
| return WordEqual(cell_value, invalid); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsArraySpeciesProtectorCellInvalid() { |
| Node* invalid = SmiConstant(Isolate::kProtectorInvalid); |
| Node* cell = LoadRoot(RootIndex::kArraySpeciesProtector); |
| Node* cell_value = LoadObjectField(cell, PropertyCell::kValueOffset); |
| return WordEqual(cell_value, invalid); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsTypedArraySpeciesProtectorCellInvalid() { |
| Node* invalid = SmiConstant(Isolate::kProtectorInvalid); |
| Node* cell = LoadRoot(RootIndex::kTypedArraySpeciesProtector); |
| Node* cell_value = LoadObjectField(cell, PropertyCell::kValueOffset); |
| return WordEqual(cell_value, invalid); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsRegExpSpeciesProtectorCellInvalid() { |
| Node* invalid = SmiConstant(Isolate::kProtectorInvalid); |
| Node* cell = LoadRoot(RootIndex::kRegExpSpeciesProtector); |
| Node* cell_value = LoadObjectField(cell, PropertyCell::kValueOffset); |
| return WordEqual(cell_value, invalid); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsPromiseSpeciesProtectorCellInvalid() { |
| Node* invalid = SmiConstant(Isolate::kProtectorInvalid); |
| Node* cell = LoadRoot(RootIndex::kPromiseSpeciesProtector); |
| Node* cell_value = LoadObjectField(cell, PropertyCell::kValueOffset); |
| return WordEqual(cell_value, invalid); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsPrototypeInitialArrayPrototype( |
| SloppyTNode<Context> context, SloppyTNode<Map> map) { |
| Node* const native_context = LoadNativeContext(context); |
| Node* const initial_array_prototype = LoadContextElement( |
| native_context, Context::INITIAL_ARRAY_PROTOTYPE_INDEX); |
| Node* proto = LoadMapPrototype(map); |
| return WordEqual(proto, initial_array_prototype); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsPrototypeTypedArrayPrototype( |
| SloppyTNode<Context> context, SloppyTNode<Map> map) { |
| TNode<Context> const native_context = LoadNativeContext(context); |
| TNode<Object> const typed_array_prototype = |
| LoadContextElement(native_context, Context::TYPED_ARRAY_PROTOTYPE_INDEX); |
| TNode<HeapObject> proto = LoadMapPrototype(map); |
| TNode<HeapObject> proto_of_proto = Select<HeapObject>( |
| IsJSObject(proto), [=] { return LoadMapPrototype(LoadMap(proto)); }, |
| [=] { return NullConstant(); }); |
| return WordEqual(proto_of_proto, typed_array_prototype); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsFastAliasedArgumentsMap( |
| TNode<Context> context, TNode<Map> map) { |
| TNode<Context> const native_context = LoadNativeContext(context); |
| TNode<Object> const arguments_map = LoadContextElement( |
| native_context, Context::FAST_ALIASED_ARGUMENTS_MAP_INDEX); |
| return WordEqual(arguments_map, map); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsSlowAliasedArgumentsMap( |
| TNode<Context> context, TNode<Map> map) { |
| TNode<Context> const native_context = LoadNativeContext(context); |
| TNode<Object> const arguments_map = LoadContextElement( |
| native_context, Context::SLOW_ALIASED_ARGUMENTS_MAP_INDEX); |
| return WordEqual(arguments_map, map); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsSloppyArgumentsMap(TNode<Context> context, |
| TNode<Map> map) { |
| TNode<Context> const native_context = LoadNativeContext(context); |
| TNode<Object> const arguments_map = |
| LoadContextElement(native_context, Context::SLOPPY_ARGUMENTS_MAP_INDEX); |
| return WordEqual(arguments_map, map); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsStrictArgumentsMap(TNode<Context> context, |
| TNode<Map> map) { |
| TNode<Context> const native_context = LoadNativeContext(context); |
| TNode<Object> const arguments_map = |
| LoadContextElement(native_context, Context::STRICT_ARGUMENTS_MAP_INDEX); |
| return WordEqual(arguments_map, map); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::TaggedIsCallable(TNode<Object> object) { |
| return Select<BoolT>( |
| TaggedIsSmi(object), [=] { return Int32FalseConstant(); }, |
| [=] { |
| return IsCallableMap(LoadMap(UncheckedCast<HeapObject>(object))); |
| }); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsCallable(SloppyTNode<HeapObject> object) { |
| return IsCallableMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsCell(SloppyTNode<HeapObject> object) { |
| return WordEqual(LoadMap(object), LoadRoot(RootIndex::kCellMap)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsCode(SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, CODE_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsConstructorMap(SloppyTNode<Map> map) { |
| CSA_ASSERT(this, IsMap(map)); |
| return IsSetWord32<Map::IsConstructorBit>(LoadMapBitField(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsConstructor(SloppyTNode<HeapObject> object) { |
| return IsConstructorMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsFunctionWithPrototypeSlotMap( |
| SloppyTNode<Map> map) { |
| CSA_ASSERT(this, IsMap(map)); |
| return IsSetWord32<Map::HasPrototypeSlotBit>(LoadMapBitField(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsSpecialReceiverInstanceType( |
| TNode<Int32T> instance_type) { |
| STATIC_ASSERT(JS_GLOBAL_OBJECT_TYPE <= LAST_SPECIAL_RECEIVER_TYPE); |
| return Int32LessThanOrEqual(instance_type, |
| Int32Constant(LAST_SPECIAL_RECEIVER_TYPE)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsCustomElementsReceiverInstanceType( |
| TNode<Int32T> instance_type) { |
| return Int32LessThanOrEqual(instance_type, |
| Int32Constant(LAST_CUSTOM_ELEMENTS_RECEIVER)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsStringInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| STATIC_ASSERT(INTERNALIZED_STRING_TYPE == FIRST_TYPE); |
| return Int32LessThan(instance_type, Int32Constant(FIRST_NONSTRING_TYPE)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsOneByteStringInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| CSA_ASSERT(this, IsStringInstanceType(instance_type)); |
| return Word32Equal( |
| Word32And(instance_type, Int32Constant(kStringEncodingMask)), |
| Int32Constant(kOneByteStringTag)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsSequentialStringInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| CSA_ASSERT(this, IsStringInstanceType(instance_type)); |
| return Word32Equal( |
| Word32And(instance_type, Int32Constant(kStringRepresentationMask)), |
| Int32Constant(kSeqStringTag)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsConsStringInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| CSA_ASSERT(this, IsStringInstanceType(instance_type)); |
| return Word32Equal( |
| Word32And(instance_type, Int32Constant(kStringRepresentationMask)), |
| Int32Constant(kConsStringTag)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsIndirectStringInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| CSA_ASSERT(this, IsStringInstanceType(instance_type)); |
| STATIC_ASSERT(kIsIndirectStringMask == 0x1); |
| STATIC_ASSERT(kIsIndirectStringTag == 0x1); |
| return UncheckedCast<BoolT>( |
| Word32And(instance_type, Int32Constant(kIsIndirectStringMask))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsExternalStringInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| CSA_ASSERT(this, IsStringInstanceType(instance_type)); |
| return Word32Equal( |
| Word32And(instance_type, Int32Constant(kStringRepresentationMask)), |
| Int32Constant(kExternalStringTag)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsUncachedExternalStringInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| CSA_ASSERT(this, IsStringInstanceType(instance_type)); |
| STATIC_ASSERT(kUncachedExternalStringTag != 0); |
| return IsSetWord32(instance_type, kUncachedExternalStringMask); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSReceiverInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| STATIC_ASSERT(LAST_JS_RECEIVER_TYPE == LAST_TYPE); |
| return Int32GreaterThanOrEqual(instance_type, |
| Int32Constant(FIRST_JS_RECEIVER_TYPE)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSReceiverMap(SloppyTNode<Map> map) { |
| return IsJSReceiverInstanceType(LoadMapInstanceType(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSReceiver(SloppyTNode<HeapObject> object) { |
| return IsJSReceiverMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNullOrJSReceiver( |
| SloppyTNode<HeapObject> object) { |
| return UncheckedCast<BoolT>(Word32Or(IsJSReceiver(object), IsNull(object))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNullOrUndefined(SloppyTNode<Object> value) { |
| return UncheckedCast<BoolT>(Word32Or(IsUndefined(value), IsNull(value))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSGlobalProxyInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return InstanceTypeEqual(instance_type, JS_GLOBAL_PROXY_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSObjectInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| STATIC_ASSERT(LAST_JS_OBJECT_TYPE == LAST_TYPE); |
| return Int32GreaterThanOrEqual(instance_type, |
| Int32Constant(FIRST_JS_OBJECT_TYPE)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSObjectMap(SloppyTNode<Map> map) { |
| CSA_ASSERT(this, IsMap(map)); |
| return IsJSObjectInstanceType(LoadMapInstanceType(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSObject(SloppyTNode<HeapObject> object) { |
| return IsJSObjectMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSPromiseMap(SloppyTNode<Map> map) { |
| CSA_ASSERT(this, IsMap(map)); |
| return InstanceTypeEqual(LoadMapInstanceType(map), JS_PROMISE_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSPromise(SloppyTNode<HeapObject> object) { |
| return IsJSPromiseMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSProxy(SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, JS_PROXY_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSGlobalProxy( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, JS_GLOBAL_PROXY_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsMap(SloppyTNode<HeapObject> map) { |
| return IsMetaMap(LoadMap(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSValueInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return InstanceTypeEqual(instance_type, JS_VALUE_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSValue(SloppyTNode<HeapObject> object) { |
| return IsJSValueMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSValueMap(SloppyTNode<Map> map) { |
| return IsJSValueInstanceType(LoadMapInstanceType(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSArrayInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return InstanceTypeEqual(instance_type, JS_ARRAY_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSArray(SloppyTNode<HeapObject> object) { |
| return IsJSArrayMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSArrayMap(SloppyTNode<Map> map) { |
| return IsJSArrayInstanceType(LoadMapInstanceType(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSArrayIterator( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, JS_ARRAY_ITERATOR_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSAsyncGeneratorObject( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, JS_ASYNC_GENERATOR_OBJECT_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsContext(SloppyTNode<HeapObject> object) { |
| Node* instance_type = LoadInstanceType(object); |
| return UncheckedCast<BoolT>(Word32And( |
| Int32GreaterThanOrEqual(instance_type, Int32Constant(FIRST_CONTEXT_TYPE)), |
| Int32LessThanOrEqual(instance_type, Int32Constant(LAST_CONTEXT_TYPE)))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsFixedArray(SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, FIXED_ARRAY_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsFixedArraySubclass( |
| SloppyTNode<HeapObject> object) { |
| Node* instance_type = LoadInstanceType(object); |
| return UncheckedCast<BoolT>( |
| Word32And(Int32GreaterThanOrEqual(instance_type, |
| Int32Constant(FIRST_FIXED_ARRAY_TYPE)), |
| Int32LessThanOrEqual(instance_type, |
| Int32Constant(LAST_FIXED_ARRAY_TYPE)))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNotWeakFixedArraySubclass( |
| SloppyTNode<HeapObject> object) { |
| Node* instance_type = LoadInstanceType(object); |
| return UncheckedCast<BoolT>(Word32Or( |
| Int32LessThan(instance_type, Int32Constant(FIRST_WEAK_FIXED_ARRAY_TYPE)), |
| Int32GreaterThan(instance_type, |
| Int32Constant(LAST_WEAK_FIXED_ARRAY_TYPE)))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsPromiseCapability( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, PROMISE_CAPABILITY_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsPropertyArray( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, PROPERTY_ARRAY_TYPE); |
| } |
| |
| // This complicated check is due to elements oddities. If a smi array is empty |
| // after Array.p.shift, it is replaced by the empty array constant. If it is |
| // later filled with a double element, we try to grow it but pass in a double |
| // elements kind. Usually this would cause a size mismatch (since the source |
| // fixed array has HOLEY_ELEMENTS and destination has |
| // HOLEY_DOUBLE_ELEMENTS), but we don't have to worry about it when the |
| // source array is empty. |
| // TODO(jgruber): It might we worth creating an empty_double_array constant to |
| // simplify this case. |
| TNode<BoolT> CodeStubAssembler::IsFixedArrayWithKindOrEmpty( |
| SloppyTNode<HeapObject> object, ElementsKind kind) { |
| Label out(this); |
| TVARIABLE(BoolT, var_result, Int32TrueConstant()); |
| |
| GotoIf(IsFixedArrayWithKind(object, kind), &out); |
| |
| TNode<Smi> const length = LoadFixedArrayBaseLength(CAST(object)); |
| GotoIf(SmiEqual(length, SmiConstant(0)), &out); |
| |
| var_result = Int32FalseConstant(); |
| Goto(&out); |
| |
| BIND(&out); |
| return var_result.value(); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsFixedArrayWithKind( |
| SloppyTNode<HeapObject> object, ElementsKind kind) { |
| if (IsDoubleElementsKind(kind)) { |
| return IsFixedDoubleArray(object); |
| } else { |
| DCHECK(IsSmiOrObjectElementsKind(kind)); |
| return IsFixedArraySubclass(object); |
| } |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsBoolean(SloppyTNode<HeapObject> object) { |
| return IsBooleanMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsPropertyCell(SloppyTNode<HeapObject> object) { |
| return IsPropertyCellMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsAccessorInfo(SloppyTNode<HeapObject> object) { |
| return IsAccessorInfoMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsAccessorPair(SloppyTNode<HeapObject> object) { |
| return IsAccessorPairMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsAllocationSite( |
| SloppyTNode<HeapObject> object) { |
| return IsAllocationSiteInstanceType(LoadInstanceType(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsAnyHeapNumber( |
| SloppyTNode<HeapObject> object) { |
| return UncheckedCast<BoolT>( |
| Word32Or(IsMutableHeapNumber(object), IsHeapNumber(object))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsHeapNumber(SloppyTNode<HeapObject> object) { |
| return IsHeapNumberMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsHeapNumberInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return InstanceTypeEqual(instance_type, HEAP_NUMBER_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsOddball(SloppyTNode<HeapObject> object) { |
| return IsOddballInstanceType(LoadInstanceType(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsOddballInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return InstanceTypeEqual(instance_type, ODDBALL_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsMutableHeapNumber( |
| SloppyTNode<HeapObject> object) { |
| return IsMutableHeapNumberMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsFeedbackCell(SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, FEEDBACK_CELL_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsFeedbackVector( |
| SloppyTNode<HeapObject> object) { |
| return IsFeedbackVectorMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsName(SloppyTNode<HeapObject> object) { |
| return IsNameInstanceType(LoadInstanceType(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNameInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return Int32LessThanOrEqual(instance_type, Int32Constant(LAST_NAME_TYPE)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsString(SloppyTNode<HeapObject> object) { |
| return IsStringInstanceType(LoadInstanceType(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsSymbolInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return InstanceTypeEqual(instance_type, SYMBOL_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsSymbol(SloppyTNode<HeapObject> object) { |
| return IsSymbolMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsBigIntInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return InstanceTypeEqual(instance_type, BIGINT_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsBigInt(SloppyTNode<HeapObject> object) { |
| return IsBigIntInstanceType(LoadInstanceType(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsPrimitiveInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return Int32LessThanOrEqual(instance_type, |
| Int32Constant(LAST_PRIMITIVE_TYPE)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsPrivateSymbol( |
| SloppyTNode<HeapObject> object) { |
| return Select<BoolT>(IsSymbol(object), |
| [=] { |
| TNode<Symbol> symbol = CAST(object); |
| TNode<Uint32T> flags = LoadObjectField<Uint32T>( |
| symbol, Symbol::kFlagsOffset); |
| return IsSetWord32<Symbol::IsPrivateBit>(flags); |
| }, |
| [=] { return Int32FalseConstant(); }); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNativeContext( |
| SloppyTNode<HeapObject> object) { |
| return WordEqual(LoadMap(object), LoadRoot(RootIndex::kNativeContextMap)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsFixedDoubleArray( |
| SloppyTNode<HeapObject> object) { |
| return WordEqual(LoadMap(object), FixedDoubleArrayMapConstant()); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsHashTable(SloppyTNode<HeapObject> object) { |
| Node* instance_type = LoadInstanceType(object); |
| return UncheckedCast<BoolT>( |
| Word32And(Int32GreaterThanOrEqual(instance_type, |
| Int32Constant(FIRST_HASH_TABLE_TYPE)), |
| Int32LessThanOrEqual(instance_type, |
| Int32Constant(LAST_HASH_TABLE_TYPE)))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsEphemeronHashTable( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, EPHEMERON_HASH_TABLE_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNameDictionary( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, NAME_DICTIONARY_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsGlobalDictionary( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, GLOBAL_DICTIONARY_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNumberDictionary( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, NUMBER_DICTIONARY_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSGeneratorObject( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, JS_GENERATOR_OBJECT_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSFunctionInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return InstanceTypeEqual(instance_type, JS_FUNCTION_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsAllocationSiteInstanceType( |
| SloppyTNode<Int32T> instance_type) { |
| return InstanceTypeEqual(instance_type, ALLOCATION_SITE_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSFunction(SloppyTNode<HeapObject> object) { |
| return IsJSFunctionMap(LoadMap(object)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSFunctionMap(SloppyTNode<Map> map) { |
| return IsJSFunctionInstanceType(LoadMapInstanceType(map)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSTypedArray(SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, JS_TYPED_ARRAY_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSArrayBuffer( |
| SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, JS_ARRAY_BUFFER_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSDataView(TNode<HeapObject> object) { |
| return HasInstanceType(object, JS_DATA_VIEW_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsFixedTypedArray( |
| SloppyTNode<HeapObject> object) { |
| TNode<Int32T> instance_type = LoadInstanceType(object); |
| return UncheckedCast<BoolT>(Word32And( |
| Int32GreaterThanOrEqual(instance_type, |
| Int32Constant(FIRST_FIXED_TYPED_ARRAY_TYPE)), |
| Int32LessThanOrEqual(instance_type, |
| Int32Constant(LAST_FIXED_TYPED_ARRAY_TYPE)))); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsJSRegExp(SloppyTNode<HeapObject> object) { |
| return HasInstanceType(object, JS_REGEXP_TYPE); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNumber(SloppyTNode<Object> object) { |
| return Select<BoolT>(TaggedIsSmi(object), [=] { return Int32TrueConstant(); }, |
| [=] { return IsHeapNumber(CAST(object)); }); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNumeric(SloppyTNode<Object> object) { |
| return Select<BoolT>( |
| TaggedIsSmi(object), [=] { return Int32TrueConstant(); }, |
| [=] { |
| return UncheckedCast<BoolT>( |
| Word32Or(IsHeapNumber(CAST(object)), IsBigInt(CAST(object)))); |
| }); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNumberNormalized(SloppyTNode<Number> number) { |
| TVARIABLE(BoolT, var_result, Int32TrueConstant()); |
| Label out(this); |
| |
| GotoIf(TaggedIsSmi(number), &out); |
| |
| TNode<Float64T> value = LoadHeapNumberValue(CAST(number)); |
| TNode<Float64T> smi_min = |
| Float64Constant(static_cast<double>(Smi::kMinValue)); |
| TNode<Float64T> smi_max = |
| Float64Constant(static_cast<double>(Smi::kMaxValue)); |
| |
| GotoIf(Float64LessThan(value, smi_min), &out); |
| GotoIf(Float64GreaterThan(value, smi_max), &out); |
| GotoIfNot(Float64Equal(value, value), &out); // NaN. |
| |
| var_result = Int32FalseConstant(); |
| Goto(&out); |
| |
| BIND(&out); |
| return var_result.value(); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNumberPositive(SloppyTNode<Number> number) { |
| return Select<BoolT>(TaggedIsSmi(number), |
| [=] { return TaggedIsPositiveSmi(number); }, |
| [=] { return IsHeapNumberPositive(CAST(number)); }); |
| } |
| |
| // TODO(cbruni): Use TNode<HeapNumber> instead of custom name. |
| TNode<BoolT> CodeStubAssembler::IsHeapNumberPositive(TNode<HeapNumber> number) { |
| TNode<Float64T> value = LoadHeapNumberValue(number); |
| TNode<Float64T> float_zero = Float64Constant(0.); |
| return Float64GreaterThanOrEqual(value, float_zero); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNumberNonNegativeSafeInteger( |
| TNode<Number> number) { |
| return Select<BoolT>( |
| // TODO(cbruni): Introduce TaggedIsNonNegateSmi to avoid confusion. |
| TaggedIsSmi(number), [=] { return TaggedIsPositiveSmi(number); }, |
| [=] { |
| TNode<HeapNumber> heap_number = CAST(number); |
| return Select<BoolT>(IsInteger(heap_number), |
| [=] { return IsHeapNumberPositive(heap_number); }, |
| [=] { return Int32FalseConstant(); }); |
| }); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsSafeInteger(TNode<Object> number) { |
| return Select<BoolT>( |
| TaggedIsSmi(number), [=] { return Int32TrueConstant(); }, |
| [=] { |
| return Select<BoolT>( |
| IsHeapNumber(CAST(number)), |
| [=] { return IsSafeInteger(UncheckedCast<HeapNumber>(number)); }, |
| [=] { return Int32FalseConstant(); }); |
| }); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsSafeInteger(TNode<HeapNumber> number) { |
| // Load the actual value of {number}. |
| TNode<Float64T> number_value = LoadHeapNumberValue(number); |
| // Truncate the value of {number} to an integer (or an infinity). |
| TNode<Float64T> integer = Float64Trunc(number_value); |
| |
| return Select<BoolT>( |
| // Check if {number}s value matches the integer (ruling out the |
| // infinities). |
| Float64Equal(Float64Sub(number_value, integer), Float64Constant(0.0)), |
| [=] { |
| // Check if the {integer} value is in safe integer range. |
| return Float64LessThanOrEqual(Float64Abs(integer), |
| Float64Constant(kMaxSafeInteger)); |
| }, |
| [=] { return Int32FalseConstant(); }); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsInteger(TNode<Object> number) { |
| return Select<BoolT>( |
| TaggedIsSmi(number), [=] { return Int32TrueConstant(); }, |
| [=] { |
| return Select<BoolT>( |
| IsHeapNumber(CAST(number)), |
| [=] { return IsInteger(UncheckedCast<HeapNumber>(number)); }, |
| [=] { return Int32FalseConstant(); }); |
| }); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsInteger(TNode<HeapNumber> number) { |
| TNode<Float64T> number_value = LoadHeapNumberValue(number); |
| // Truncate the value of {number} to an integer (or an infinity). |
| TNode<Float64T> integer = Float64Trunc(number_value); |
| // Check if {number}s value matches the integer (ruling out the infinities). |
| return Float64Equal(Float64Sub(number_value, integer), Float64Constant(0.0)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsHeapNumberUint32(TNode<HeapNumber> number) { |
| // Check that the HeapNumber is a valid uint32 |
| return Select<BoolT>( |
| IsHeapNumberPositive(number), |
| [=] { |
| TNode<Float64T> value = LoadHeapNumberValue(number); |
| TNode<Uint32T> int_value = Unsigned(TruncateFloat64ToWord32(value)); |
| return Float64Equal(value, ChangeUint32ToFloat64(int_value)); |
| }, |
| [=] { return Int32FalseConstant(); }); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsNumberArrayIndex(TNode<Number> number) { |
| return Select<BoolT>(TaggedIsSmi(number), |
| [=] { return TaggedIsPositiveSmi(number); }, |
| [=] { return IsHeapNumberUint32(CAST(number)); }); |
| } |
| |
| Node* CodeStubAssembler::FixedArraySizeDoesntFitInNewSpace(Node* element_count, |
| int base_size, |
| ParameterMode mode) { |
| int max_newspace_elements = |
| (kMaxRegularHeapObjectSize - base_size) / kTaggedSize; |
| return IntPtrOrSmiGreaterThan( |
| element_count, IntPtrOrSmiConstant(max_newspace_elements, mode), mode); |
| } |
| |
| TNode<Int32T> CodeStubAssembler::StringCharCodeAt(SloppyTNode<String> string, |
| SloppyTNode<IntPtrT> index) { |
| CSA_ASSERT(this, IsString(string)); |
| |
| CSA_ASSERT(this, IntPtrGreaterThanOrEqual(index, IntPtrConstant(0))); |
| CSA_ASSERT(this, IntPtrLessThan(index, LoadStringLengthAsWord(string))); |
| |
| TVARIABLE(Int32T, var_result); |
| |
| Label return_result(this), if_runtime(this, Label::kDeferred), |
| if_stringistwobyte(this), if_stringisonebyte(this); |
| |
| ToDirectStringAssembler to_direct(state(), string); |
| to_direct.TryToDirect(&if_runtime); |
| Node* const offset = IntPtrAdd(index, to_direct.offset()); |
| Node* const instance_type = to_direct.instance_type(); |
| |
| Node* const string_data = to_direct.PointerToData(&if_runtime); |
| |
| // Check if the {string} is a TwoByteSeqString or a OneByteSeqString. |
| Branch(IsOneByteStringInstanceType(instance_type), &if_stringisonebyte, |
| &if_stringistwobyte); |
| |
| BIND(&if_stringisonebyte); |
| { |
| var_result = |
| UncheckedCast<Int32T>(Load(MachineType::Uint8(), string_data, offset)); |
| Goto(&return_result); |
| } |
| |
| BIND(&if_stringistwobyte); |
| { |
| var_result = |
| UncheckedCast<Int32T>(Load(MachineType::Uint16(), string_data, |
| WordShl(offset, IntPtrConstant(1)))); |
| Goto(&return_result); |
| } |
| |
| BIND(&if_runtime); |
| { |
| Node* result = CallRuntime(Runtime::kStringCharCodeAt, NoContextConstant(), |
| string, SmiTag(index)); |
| var_result = SmiToInt32(result); |
| Goto(&return_result); |
| } |
| |
| BIND(&return_result); |
| return var_result.value(); |
| } |
| |
| TNode<String> CodeStubAssembler::StringFromSingleCharCode(TNode<Int32T> code) { |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| |
| // Check if the {code} is a one-byte char code. |
| Label if_codeisonebyte(this), if_codeistwobyte(this, Label::kDeferred), |
| if_done(this); |
| Branch(Int32LessThanOrEqual(code, Int32Constant(String::kMaxOneByteCharCode)), |
| &if_codeisonebyte, &if_codeistwobyte); |
| BIND(&if_codeisonebyte); |
| { |
| // Load the isolate wide single character string cache. |
| TNode<FixedArray> cache = |
| CAST(LoadRoot(RootIndex::kSingleCharacterStringCache)); |
| TNode<IntPtrT> code_index = Signed(ChangeUint32ToWord(code)); |
| |
| // Check if we have an entry for the {code} in the single character string |
| // cache already. |
| Label if_entryisundefined(this, Label::kDeferred), |
| if_entryisnotundefined(this); |
| Node* entry = UnsafeLoadFixedArrayElement(cache, code_index); |
| Branch(IsUndefined(entry), &if_entryisundefined, &if_entryisnotundefined); |
| |
| BIND(&if_entryisundefined); |
| { |
| // Allocate a new SeqOneByteString for {code} and store it in the {cache}. |
| TNode<String> result = AllocateSeqOneByteString(1); |
| StoreNoWriteBarrier( |
| MachineRepresentation::kWord8, result, |
| IntPtrConstant(SeqOneByteString::kHeaderSize - kHeapObjectTag), code); |
| StoreFixedArrayElement(cache, code_index, result); |
| var_result.Bind(result); |
| Goto(&if_done); |
| } |
| |
| BIND(&if_entryisnotundefined); |
| { |
| // Return the entry from the {cache}. |
| var_result.Bind(entry); |
| Goto(&if_done); |
| } |
| } |
| |
| BIND(&if_codeistwobyte); |
| { |
| // Allocate a new SeqTwoByteString for {code}. |
| Node* result = AllocateSeqTwoByteString(1); |
| StoreNoWriteBarrier( |
| MachineRepresentation::kWord16, result, |
| IntPtrConstant(SeqTwoByteString::kHeaderSize - kHeapObjectTag), code); |
| var_result.Bind(result); |
| Goto(&if_done); |
| } |
| |
| BIND(&if_done); |
| CSA_ASSERT(this, IsString(var_result.value())); |
| return CAST(var_result.value()); |
| } |
| |
| // A wrapper around CopyStringCharacters which determines the correct string |
| // encoding, allocates a corresponding sequential string, and then copies the |
| // given character range using CopyStringCharacters. |
| // |from_string| must be a sequential string. |
| // 0 <= |from_index| <= |from_index| + |character_count| < from_string.length. |
| TNode<String> CodeStubAssembler::AllocAndCopyStringCharacters( |
| Node* from, Node* from_instance_type, TNode<IntPtrT> from_index, |
| TNode<IntPtrT> character_count) { |
| Label end(this), one_byte_sequential(this), two_byte_sequential(this); |
| TVARIABLE(String, var_result); |
| |
| Branch(IsOneByteStringInstanceType(from_instance_type), &one_byte_sequential, |
| &two_byte_sequential); |
| |
| // The subject string is a sequential one-byte string. |
| BIND(&one_byte_sequential); |
| { |
| TNode<String> result = AllocateSeqOneByteString( |
| NoContextConstant(), Unsigned(TruncateIntPtrToInt32(character_count))); |
| CopyStringCharacters(from, result, from_index, IntPtrConstant(0), |
| character_count, String::ONE_BYTE_ENCODING, |
| String::ONE_BYTE_ENCODING); |
| var_result = result; |
| Goto(&end); |
| } |
| |
| // The subject string is a sequential two-byte string. |
| BIND(&two_byte_sequential); |
| { |
| TNode<String> result = AllocateSeqTwoByteString( |
| NoContextConstant(), Unsigned(TruncateIntPtrToInt32(character_count))); |
| CopyStringCharacters(from, result, from_index, IntPtrConstant(0), |
| character_count, String::TWO_BYTE_ENCODING, |
| String::TWO_BYTE_ENCODING); |
| var_result = result; |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| TNode<String> CodeStubAssembler::SubString(TNode<String> string, |
| TNode<IntPtrT> from, |
| TNode<IntPtrT> to) { |
| TVARIABLE(String, var_result); |
| ToDirectStringAssembler to_direct(state(), string); |
| Label end(this), runtime(this); |
| |
| TNode<IntPtrT> const substr_length = IntPtrSub(to, from); |
| TNode<IntPtrT> const string_length = LoadStringLengthAsWord(string); |
| |
| // Begin dispatching based on substring length. |
| |
| Label original_string_or_invalid_length(this); |
| GotoIf(UintPtrGreaterThanOrEqual(substr_length, string_length), |
| &original_string_or_invalid_length); |
| |
| // A real substring (substr_length < string_length). |
| Label empty(this); |
| GotoIf(IntPtrEqual(substr_length, IntPtrConstant(0)), &empty); |
| |
| Label single_char(this); |
| GotoIf(IntPtrEqual(substr_length, IntPtrConstant(1)), &single_char); |
| |
| // Deal with different string types: update the index if necessary |
| // and extract the underlying string. |
| |
| TNode<String> direct_string = to_direct.TryToDirect(&runtime); |
| TNode<IntPtrT> offset = IntPtrAdd(from, to_direct.offset()); |
| Node* const instance_type = to_direct.instance_type(); |
| |
| // The subject string can only be external or sequential string of either |
| // encoding at this point. |
| Label external_string(this); |
| { |
| if (FLAG_string_slices) { |
| Label next(this); |
| |
| // Short slice. Copy instead of slicing. |
| GotoIf(IntPtrLessThan(substr_length, |
| IntPtrConstant(SlicedString::kMinLength)), |
| &next); |
| |
| // Allocate new sliced string. |
| |
| Counters* counters = isolate()->counters(); |
| IncrementCounter(counters->sub_string_native(), 1); |
| |
| Label one_byte_slice(this), two_byte_slice(this); |
| Branch(IsOneByteStringInstanceType(to_direct.instance_type()), |
| &one_byte_slice, &two_byte_slice); |
| |
| BIND(&one_byte_slice); |
| { |
| var_result = AllocateSlicedOneByteString( |
| Unsigned(TruncateIntPtrToInt32(substr_length)), direct_string, |
| SmiTag(offset)); |
| Goto(&end); |
| } |
| |
| BIND(&two_byte_slice); |
| { |
| var_result = AllocateSlicedTwoByteString( |
| Unsigned(TruncateIntPtrToInt32(substr_length)), direct_string, |
| SmiTag(offset)); |
| Goto(&end); |
| } |
| |
| BIND(&next); |
| } |
| |
| // The subject string can only be external or sequential string of either |
| // encoding at this point. |
| GotoIf(to_direct.is_external(), &external_string); |
| |
| var_result = AllocAndCopyStringCharacters(direct_string, instance_type, |
| offset, substr_length); |
| |
| Counters* counters = isolate()->counters(); |
| IncrementCounter(counters->sub_string_native(), 1); |
| |
| Goto(&end); |
| } |
| |
| // Handle external string. |
| BIND(&external_string); |
| { |
| Node* const fake_sequential_string = to_direct.PointerToString(&runtime); |
| |
| var_result = AllocAndCopyStringCharacters( |
| fake_sequential_string, instance_type, offset, substr_length); |
| |
| Counters* counters = isolate()->counters(); |
| IncrementCounter(counters->sub_string_native(), 1); |
| |
| Goto(&end); |
| } |
| |
| BIND(&empty); |
| { |
| var_result = EmptyStringConstant(); |
| Goto(&end); |
| } |
| |
| // Substrings of length 1 are generated through CharCodeAt and FromCharCode. |
| BIND(&single_char); |
| { |
| TNode<Int32T> char_code = StringCharCodeAt(string, from); |
| var_result = StringFromSingleCharCode(char_code); |
| Goto(&end); |
| } |
| |
| BIND(&original_string_or_invalid_length); |
| { |
| CSA_ASSERT(this, IntPtrEqual(substr_length, string_length)); |
| |
| // Equal length - check if {from, to} == {0, str.length}. |
| GotoIf(UintPtrGreaterThan(from, IntPtrConstant(0)), &runtime); |
| |
| // Return the original string (substr_length == string_length). |
| |
| Counters* counters = isolate()->counters(); |
| IncrementCounter(counters->sub_string_native(), 1); |
| |
| var_result = string; |
| Goto(&end); |
| } |
| |
| // Fall back to a runtime call. |
| BIND(&runtime); |
| { |
| var_result = |
| CAST(CallRuntime(Runtime::kStringSubstring, NoContextConstant(), string, |
| SmiTag(from), SmiTag(to))); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| ToDirectStringAssembler::ToDirectStringAssembler( |
| compiler::CodeAssemblerState* state, Node* string, Flags flags) |
| : CodeStubAssembler(state), |
| var_string_(this, MachineRepresentation::kTagged, string), |
| var_instance_type_(this, MachineRepresentation::kWord32), |
| var_offset_(this, MachineType::PointerRepresentation()), |
| var_is_external_(this, MachineRepresentation::kWord32), |
| flags_(flags) { |
| CSA_ASSERT(this, TaggedIsNotSmi(string)); |
| CSA_ASSERT(this, IsString(string)); |
| |
| var_string_.Bind(string); |
| var_offset_.Bind(IntPtrConstant(0)); |
| var_instance_type_.Bind(LoadInstanceType(string)); |
| var_is_external_.Bind(Int32Constant(0)); |
| } |
| |
| TNode<String> ToDirectStringAssembler::TryToDirect(Label* if_bailout) { |
| VariableList vars({&var_string_, &var_offset_, &var_instance_type_}, zone()); |
| Label dispatch(this, vars); |
| Label if_iscons(this); |
| Label if_isexternal(this); |
| Label if_issliced(this); |
| Label if_isthin(this); |
| Label out(this); |
| |
| Branch(IsSequentialStringInstanceType(var_instance_type_.value()), &out, |
| &dispatch); |
| |
| // Dispatch based on string representation. |
| BIND(&dispatch); |
| { |
| int32_t values[] = { |
| kSeqStringTag, kConsStringTag, kExternalStringTag, |
| kSlicedStringTag, kThinStringTag, |
| }; |
| Label* labels[] = { |
| &out, &if_iscons, &if_isexternal, &if_issliced, &if_isthin, |
| }; |
| STATIC_ASSERT(arraysize(values) == arraysize(labels)); |
| |
| Node* const representation = Word32And( |
| var_instance_type_.value(), Int32Constant(kStringRepresentationMask)); |
| Switch(representation, if_bailout, values, labels, arraysize(values)); |
| } |
| |
| // Cons string. Check whether it is flat, then fetch first part. |
| // Flat cons strings have an empty second part. |
| BIND(&if_iscons); |
| { |
| Node* const string = var_string_.value(); |
| GotoIfNot(IsEmptyString(LoadObjectField(string, ConsString::kSecondOffset)), |
| if_bailout); |
| |
| Node* const lhs = LoadObjectField(string, ConsString::kFirstOffset); |
| var_string_.Bind(lhs); |
| var_instance_type_.Bind(LoadInstanceType(lhs)); |
| |
| Goto(&dispatch); |
| } |
| |
| // Sliced string. Fetch parent and correct start index by offset. |
| BIND(&if_issliced); |
| { |
| if (!FLAG_string_slices || (flags_ & kDontUnpackSlicedStrings)) { |
| Goto(if_bailout); |
| } else { |
| Node* const string = var_string_.value(); |
| Node* const sliced_offset = |
| LoadAndUntagObjectField(string, SlicedString::kOffsetOffset); |
| var_offset_.Bind(IntPtrAdd(var_offset_.value(), sliced_offset)); |
| |
| Node* const parent = LoadObjectField(string, SlicedString::kParentOffset); |
| var_string_.Bind(parent); |
| var_instance_type_.Bind(LoadInstanceType(parent)); |
| |
| Goto(&dispatch); |
| } |
| } |
| |
| // Thin string. Fetch the actual string. |
| BIND(&if_isthin); |
| { |
| Node* const string = var_string_.value(); |
| Node* const actual_string = |
| LoadObjectField(string, ThinString::kActualOffset); |
| Node* const actual_instance_type = LoadInstanceType(actual_string); |
| |
| var_string_.Bind(actual_string); |
| var_instance_type_.Bind(actual_instance_type); |
| |
| Goto(&dispatch); |
| } |
| |
| // External string. |
| BIND(&if_isexternal); |
| var_is_external_.Bind(Int32Constant(1)); |
| Goto(&out); |
| |
| BIND(&out); |
| return CAST(var_string_.value()); |
| } |
| |
| TNode<RawPtrT> ToDirectStringAssembler::TryToSequential( |
| StringPointerKind ptr_kind, Label* if_bailout) { |
| CHECK(ptr_kind == PTR_TO_DATA || ptr_kind == PTR_TO_STRING); |
| |
| TVARIABLE(RawPtrT, var_result); |
| Label out(this), if_issequential(this), if_isexternal(this, Label::kDeferred); |
| Branch(is_external(), &if_isexternal, &if_issequential); |
| |
| BIND(&if_issequential); |
| { |
| STATIC_ASSERT(SeqOneByteString::kHeaderSize == |
| SeqTwoByteString::kHeaderSize); |
| TNode<IntPtrT> result = BitcastTaggedToWord(var_string_.value()); |
| if (ptr_kind == PTR_TO_DATA) { |
| result = IntPtrAdd(result, IntPtrConstant(SeqOneByteString::kHeaderSize - |
| kHeapObjectTag)); |
| } |
| var_result = ReinterpretCast<RawPtrT>(result); |
| Goto(&out); |
| } |
| |
| BIND(&if_isexternal); |
| { |
| GotoIf(IsUncachedExternalStringInstanceType(var_instance_type_.value()), |
| if_bailout); |
| |
| TNode<String> string = CAST(var_string_.value()); |
| TNode<IntPtrT> result = |
| LoadObjectField<IntPtrT>(string, ExternalString::kResourceDataOffset); |
| if (ptr_kind == PTR_TO_STRING) { |
| result = IntPtrSub(result, IntPtrConstant(SeqOneByteString::kHeaderSize - |
| kHeapObjectTag)); |
| } |
| var_result = ReinterpretCast<RawPtrT>(result); |
| Goto(&out); |
| } |
| |
| BIND(&out); |
| return var_result.value(); |
| } |
| |
| void CodeStubAssembler::BranchIfCanDerefIndirectString(Node* string, |
| Node* instance_type, |
| Label* can_deref, |
| Label* cannot_deref) { |
| CSA_ASSERT(this, IsString(string)); |
| Node* representation = |
| Word32And(instance_type, Int32Constant(kStringRepresentationMask)); |
| GotoIf(Word32Equal(representation, Int32Constant(kThinStringTag)), can_deref); |
| GotoIf(Word32NotEqual(representation, Int32Constant(kConsStringTag)), |
| cannot_deref); |
| // Cons string. |
| Node* rhs = LoadObjectField(string, ConsString::kSecondOffset); |
| GotoIf(IsEmptyString(rhs), can_deref); |
| Goto(cannot_deref); |
| } |
| |
| Node* CodeStubAssembler::DerefIndirectString(TNode<String> string, |
| TNode<Int32T> instance_type, |
| Label* cannot_deref) { |
| Label deref(this); |
| BranchIfCanDerefIndirectString(string, instance_type, &deref, cannot_deref); |
| BIND(&deref); |
| STATIC_ASSERT(static_cast<int>(ThinString::kActualOffset) == |
| static_cast<int>(ConsString::kFirstOffset)); |
| return LoadObjectField(string, ThinString::kActualOffset); |
| } |
| |
| void CodeStubAssembler::DerefIndirectString(Variable* var_string, |
| Node* instance_type) { |
| #ifdef DEBUG |
| Label can_deref(this), cannot_deref(this); |
| BranchIfCanDerefIndirectString(var_string->value(), instance_type, &can_deref, |
| &cannot_deref); |
| BIND(&cannot_deref); |
| DebugBreak(); // Should be able to dereference string. |
| Goto(&can_deref); |
| BIND(&can_deref); |
| #endif // DEBUG |
| |
| STATIC_ASSERT(static_cast<int>(ThinString::kActualOffset) == |
| static_cast<int>(ConsString::kFirstOffset)); |
| var_string->Bind( |
| LoadObjectField(var_string->value(), ThinString::kActualOffset)); |
| } |
| |
| void CodeStubAssembler::MaybeDerefIndirectString(Variable* var_string, |
| Node* instance_type, |
| Label* did_deref, |
| Label* cannot_deref) { |
| Label deref(this); |
| BranchIfCanDerefIndirectString(var_string->value(), instance_type, &deref, |
| cannot_deref); |
| |
| BIND(&deref); |
| { |
| DerefIndirectString(var_string, instance_type); |
| Goto(did_deref); |
| } |
| } |
| |
| void CodeStubAssembler::MaybeDerefIndirectStrings(Variable* var_left, |
| Node* left_instance_type, |
| Variable* var_right, |
| Node* right_instance_type, |
| Label* did_something) { |
| Label did_nothing_left(this), did_something_left(this), |
| didnt_do_anything(this); |
| MaybeDerefIndirectString(var_left, left_instance_type, &did_something_left, |
| &did_nothing_left); |
| |
| BIND(&did_something_left); |
| { |
| MaybeDerefIndirectString(var_right, right_instance_type, did_something, |
| did_something); |
| } |
| |
| BIND(&did_nothing_left); |
| { |
| MaybeDerefIndirectString(var_right, right_instance_type, did_something, |
| &didnt_do_anything); |
| } |
| |
| BIND(&didnt_do_anything); |
| // Fall through if neither string was an indirect string. |
| } |
| |
| TNode<String> CodeStubAssembler::StringAdd(Node* context, TNode<String> left, |
| TNode<String> right) { |
| TVARIABLE(String, result); |
| Label check_right(this), runtime(this, Label::kDeferred), cons(this), |
| done(this, &result), done_native(this, &result); |
| Counters* counters = isolate()->counters(); |
| |
| TNode<Uint32T> left_length = LoadStringLengthAsWord32(left); |
| GotoIfNot(Word32Equal(left_length, Uint32Constant(0)), &check_right); |
| result = right; |
| Goto(&done_native); |
| |
| BIND(&check_right); |
| TNode<Uint32T> right_length = LoadStringLengthAsWord32(right); |
| GotoIfNot(Word32Equal(right_length, Uint32Constant(0)), &cons); |
| result = left; |
| Goto(&done_native); |
| |
| BIND(&cons); |
| { |
| TNode<Uint32T> new_length = Uint32Add(left_length, right_length); |
| |
| // If new length is greater than String::kMaxLength, goto runtime to |
| // throw. Note: we also need to invalidate the string length protector, so |
| // can't just throw here directly. |
| GotoIf(Uint32GreaterThan(new_length, Uint32Constant(String::kMaxLength)), |
| &runtime); |
| |
| TVARIABLE(String, var_left, left); |
| TVARIABLE(String, var_right, right); |
| Variable* input_vars[2] = {&var_left, &var_right}; |
| Label non_cons(this, 2, input_vars); |
| Label slow(this, Label::kDeferred); |
| GotoIf(Uint32LessThan(new_length, Uint32Constant(ConsString::kMinLength)), |
| &non_cons); |
| |
| result = |
| AllocateConsString(new_length, var_left.value(), var_right.value()); |
| Goto(&done_native); |
| |
| BIND(&non_cons); |
| |
| Comment("Full string concatenate"); |
| Node* left_instance_type = LoadInstanceType(var_left.value()); |
| Node* right_instance_type = LoadInstanceType(var_right.value()); |
| // Compute intersection and difference of instance types. |
| |
| Node* ored_instance_types = |
| Word32Or(left_instance_type, right_instance_type); |
| Node* xored_instance_types = |
| Word32Xor(left_instance_type, right_instance_type); |
| |
| // Check if both strings have the same encoding and both are sequential. |
| GotoIf(IsSetWord32(xored_instance_types, kStringEncodingMask), &runtime); |
| GotoIf(IsSetWord32(ored_instance_types, kStringRepresentationMask), &slow); |
| |
| TNode<IntPtrT> word_left_length = Signed(ChangeUint32ToWord(left_length)); |
| TNode<IntPtrT> word_right_length = Signed(ChangeUint32ToWord(right_length)); |
| |
| Label two_byte(this); |
| GotoIf(Word32Equal(Word32And(ored_instance_types, |
| Int32Constant(kStringEncodingMask)), |
| Int32Constant(kTwoByteStringTag)), |
| &two_byte); |
| // One-byte sequential string case |
| result = AllocateSeqOneByteString(context, new_length); |
| CopyStringCharacters(var_left.value(), result.value(), IntPtrConstant(0), |
| IntPtrConstant(0), word_left_length, |
| String::ONE_BYTE_ENCODING, String::ONE_BYTE_ENCODING); |
| CopyStringCharacters(var_right.value(), result.value(), IntPtrConstant(0), |
| word_left_length, word_right_length, |
| String::ONE_BYTE_ENCODING, String::ONE_BYTE_ENCODING); |
| Goto(&done_native); |
| |
| BIND(&two_byte); |
| { |
| // Two-byte sequential string case |
| result = AllocateSeqTwoByteString(context, new_length); |
| CopyStringCharacters(var_left.value(), result.value(), IntPtrConstant(0), |
| IntPtrConstant(0), word_left_length, |
| String::TWO_BYTE_ENCODING, |
| String::TWO_BYTE_ENCODING); |
| CopyStringCharacters(var_right.value(), result.value(), IntPtrConstant(0), |
| word_left_length, word_right_length, |
| String::TWO_BYTE_ENCODING, |
| String::TWO_BYTE_ENCODING); |
| Goto(&done_native); |
| } |
| |
| BIND(&slow); |
| { |
| // Try to unwrap indirect strings, restart the above attempt on success. |
| MaybeDerefIndirectStrings(&var_left, left_instance_type, &var_right, |
| right_instance_type, &non_cons); |
| Goto(&runtime); |
| } |
| } |
| BIND(&runtime); |
| { |
| result = CAST(CallRuntime(Runtime::kStringAdd, context, left, right)); |
| Goto(&done); |
| } |
| |
| BIND(&done_native); |
| { |
| IncrementCounter(counters->string_add_native(), 1); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<String> CodeStubAssembler::StringFromSingleCodePoint( |
| TNode<Int32T> codepoint, UnicodeEncoding encoding) { |
| VARIABLE(var_result, MachineRepresentation::kTagged, EmptyStringConstant()); |
| |
| Label if_isword16(this), if_isword32(this), return_result(this); |
| |
| Branch(Uint32LessThan(codepoint, Int32Constant(0x10000)), &if_isword16, |
| &if_isword32); |
| |
| BIND(&if_isword16); |
| { |
| var_result.Bind(StringFromSingleCharCode(codepoint)); |
| Goto(&return_result); |
| } |
| |
| BIND(&if_isword32); |
| { |
| switch (encoding) { |
| case UnicodeEncoding::UTF16: |
| break; |
| case UnicodeEncoding::UTF32: { |
| // Convert UTF32 to UTF16 code units, and store as a 32 bit word. |
| Node* lead_offset = Int32Constant(0xD800 - (0x10000 >> 10)); |
| |
| // lead = (codepoint >> 10) + LEAD_OFFSET |
| Node* lead = |
| Int32Add(Word32Shr(codepoint, Int32Constant(10)), lead_offset); |
| |
| // trail = (codepoint & 0x3FF) + 0xDC00; |
| Node* trail = Int32Add(Word32And(codepoint, Int32Constant(0x3FF)), |
| Int32Constant(0xDC00)); |
| |
| // codpoint = (trail << 16) | lead; |
| codepoint = Signed(Word32Or(Word32Shl(trail, Int32Constant(16)), lead)); |
| break; |
| } |
| } |
| |
| Node* value = AllocateSeqTwoByteString(2); |
| StoreNoWriteBarrier( |
| MachineRepresentation::kWord32, value, |
| IntPtrConstant(SeqTwoByteString::kHeaderSize - kHeapObjectTag), |
| codepoint); |
| var_result.Bind(value); |
| Goto(&return_result); |
| } |
| |
| BIND(&return_result); |
| return CAST(var_result.value()); |
| } |
| |
| TNode<Number> CodeStubAssembler::StringToNumber(TNode<String> input) { |
| Label runtime(this, Label::kDeferred); |
| Label end(this); |
| |
| TVARIABLE(Number, var_result); |
| |
| // Check if string has a cached array index. |
| TNode<Uint32T> hash = LoadNameHashField(input); |
| GotoIf(IsSetWord32(hash, Name::kDoesNotContainCachedArrayIndexMask), |
| &runtime); |
| |
| var_result = |
| SmiTag(Signed(DecodeWordFromWord32<String::ArrayIndexValueBits>(hash))); |
| Goto(&end); |
| |
| BIND(&runtime); |
| { |
| var_result = |
| CAST(CallRuntime(Runtime::kStringToNumber, NoContextConstant(), input)); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| TNode<String> CodeStubAssembler::NumberToString(TNode<Number> input) { |
| TVARIABLE(String, result); |
| TVARIABLE(Smi, smi_input); |
| Label runtime(this, Label::kDeferred), if_smi(this), if_heap_number(this), |
| done(this, &result); |
| |
| // Load the number string cache. |
| Node* number_string_cache = LoadRoot(RootIndex::kNumberStringCache); |
| |
| // Make the hash mask from the length of the number string cache. It |
| // contains two elements (number and string) for each cache entry. |
| // TODO(ishell): cleanup mask handling. |
| Node* mask = |
| BitcastTaggedToWord(LoadFixedArrayBaseLength(number_string_cache)); |
| TNode<IntPtrT> one = IntPtrConstant(1); |
| mask = IntPtrSub(mask, one); |
| |
| GotoIfNot(TaggedIsSmi(input), &if_heap_number); |
| smi_input = CAST(input); |
| Goto(&if_smi); |
| |
| BIND(&if_heap_number); |
| { |
| TNode<HeapNumber> heap_number_input = CAST(input); |
| // Try normalizing the HeapNumber. |
| TryHeapNumberToSmi(heap_number_input, smi_input, &if_smi); |
| |
| // Make a hash from the two 32-bit values of the double. |
| TNode<Int32T> low = |
| LoadObjectField<Int32T>(heap_number_input, HeapNumber::kValueOffset); |
| TNode<Int32T> high = LoadObjectField<Int32T>( |
| heap_number_input, HeapNumber::kValueOffset + kIntSize); |
| TNode<Word32T> hash = Word32Xor(low, high); |
| TNode<WordT> word_hash = WordShl(ChangeInt32ToIntPtr(hash), one); |
| TNode<WordT> index = |
| WordAnd(word_hash, WordSar(mask, SmiShiftBitsConstant())); |
| |
| // Cache entry's key must be a heap number |
| Node* number_key = |
| UnsafeLoadFixedArrayElement(CAST(number_string_cache), index); |
| GotoIf(TaggedIsSmi(number_key), &runtime); |
| GotoIfNot(IsHeapNumber(number_key), &runtime); |
| |
| // Cache entry's key must match the heap number value we're looking for. |
| Node* low_compare = LoadObjectField(number_key, HeapNumber::kValueOffset, |
| MachineType::Int32()); |
| Node* high_compare = LoadObjectField( |
| number_key, HeapNumber::kValueOffset + kIntSize, MachineType::Int32()); |
| GotoIfNot(Word32Equal(low, low_compare), &runtime); |
| GotoIfNot(Word32Equal(high, high_compare), &runtime); |
| |
| // Heap number match, return value from cache entry. |
| result = CAST(UnsafeLoadFixedArrayElement(CAST(number_string_cache), index, |
| kTaggedSize)); |
| Goto(&done); |
| } |
| |
| BIND(&if_smi); |
| { |
| // Load the smi key, make sure it matches the smi we're looking for. |
| Node* smi_index = BitcastWordToTagged( |
| WordAnd(WordShl(BitcastTaggedToWord(smi_input.value()), one), mask)); |
| Node* smi_key = UnsafeLoadFixedArrayElement(CAST(number_string_cache), |
| smi_index, 0, SMI_PARAMETERS); |
| GotoIf(WordNotEqual(smi_key, smi_input.value()), &runtime); |
| |
| // Smi match, return value from cache entry. |
| result = CAST(UnsafeLoadFixedArrayElement( |
| CAST(number_string_cache), smi_index, kTaggedSize, SMI_PARAMETERS)); |
| Goto(&done); |
| } |
| |
| BIND(&runtime); |
| { |
| // No cache entry, go to the runtime. |
| result = |
| CAST(CallRuntime(Runtime::kNumberToString, NoContextConstant(), input)); |
| Goto(&done); |
| } |
| BIND(&done); |
| return result.value(); |
| } |
| |
| Node* CodeStubAssembler::NonNumberToNumberOrNumeric( |
| Node* context, Node* input, Object::Conversion mode, |
| BigIntHandling bigint_handling) { |
| CSA_ASSERT(this, Word32BinaryNot(TaggedIsSmi(input))); |
| CSA_ASSERT(this, Word32BinaryNot(IsHeapNumber(input))); |
| |
| // We might need to loop once here due to ToPrimitive conversions. |
| VARIABLE(var_input, MachineRepresentation::kTagged, input); |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| Label loop(this, &var_input); |
| Label end(this); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| // Load the current {input} value (known to be a HeapObject). |
| Node* input = var_input.value(); |
| |
| // Dispatch on the {input} instance type. |
| Node* input_instance_type = LoadInstanceType(input); |
| Label if_inputisstring(this), if_inputisoddball(this), |
| if_inputisbigint(this), if_inputisreceiver(this, Label::kDeferred), |
| if_inputisother(this, Label::kDeferred); |
| GotoIf(IsStringInstanceType(input_instance_type), &if_inputisstring); |
| GotoIf(IsBigIntInstanceType(input_instance_type), &if_inputisbigint); |
| GotoIf(InstanceTypeEqual(input_instance_type, ODDBALL_TYPE), |
| &if_inputisoddball); |
| Branch(IsJSReceiverInstanceType(input_instance_type), &if_inputisreceiver, |
| &if_inputisother); |
| |
| BIND(&if_inputisstring); |
| { |
| // The {input} is a String, use the fast stub to convert it to a Number. |
| TNode<String> string_input = CAST(input); |
| var_result.Bind(StringToNumber(string_input)); |
| Goto(&end); |
| } |
| |
| BIND(&if_inputisbigint); |
| if (mode == Object::Conversion::kToNumeric) { |
| var_result.Bind(input); |
| Goto(&end); |
| } else { |
| DCHECK_EQ(mode, Object::Conversion::kToNumber); |
| if (bigint_handling == BigIntHandling::kThrow) { |
| Goto(&if_inputisother); |
| } else { |
| DCHECK_EQ(bigint_handling, BigIntHandling::kConvertToNumber); |
| var_result.Bind(CallRuntime(Runtime::kBigIntToNumber, context, input)); |
| Goto(&end); |
| } |
| } |
| |
| BIND(&if_inputisoddball); |
| { |
| // The {input} is an Oddball, we just need to load the Number value of it. |
| var_result.Bind(LoadObjectField(input, Oddball::kToNumberOffset)); |
| Goto(&end); |
| } |
| |
| BIND(&if_inputisreceiver); |
| { |
| // The {input} is a JSReceiver, we need to convert it to a Primitive first |
| // using the ToPrimitive type conversion, preferably yielding a Number. |
| Callable callable = CodeFactory::NonPrimitiveToPrimitive( |
| isolate(), ToPrimitiveHint::kNumber); |
| Node* result = CallStub(callable, context, input); |
| |
| // Check if the {result} is already a Number/Numeric. |
| Label if_done(this), if_notdone(this); |
| Branch(mode == Object::Conversion::kToNumber ? IsNumber(result) |
| : IsNumeric(result), |
| &if_done, &if_notdone); |
| |
| BIND(&if_done); |
| { |
| // The ToPrimitive conversion already gave us a Number/Numeric, so we're |
| // done. |
| var_result.Bind(result); |
| Goto(&end); |
| } |
| |
| BIND(&if_notdone); |
| { |
| // We now have a Primitive {result}, but it's not yet a Number/Numeric. |
| var_input.Bind(result); |
| Goto(&loop); |
| } |
| } |
| |
| BIND(&if_inputisother); |
| { |
| // The {input} is something else (e.g. Symbol), let the runtime figure |
| // out the correct exception. |
| // Note: We cannot tail call to the runtime here, as js-to-wasm |
| // trampolines also use this code currently, and they declare all |
| // outgoing parameters as untagged, while we would push a tagged |
| // object here. |
| auto function_id = mode == Object::Conversion::kToNumber |
| ? Runtime::kToNumber |
| : Runtime::kToNumeric; |
| var_result.Bind(CallRuntime(function_id, context, input)); |
| Goto(&end); |
| } |
| } |
| |
| BIND(&end); |
| if (mode == Object::Conversion::kToNumeric) { |
| CSA_ASSERT(this, IsNumeric(var_result.value())); |
| } else { |
| DCHECK_EQ(mode, Object::Conversion::kToNumber); |
| CSA_ASSERT(this, IsNumber(var_result.value())); |
| } |
| return var_result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::NonNumberToNumber( |
| SloppyTNode<Context> context, SloppyTNode<HeapObject> input, |
| BigIntHandling bigint_handling) { |
| return CAST(NonNumberToNumberOrNumeric( |
| context, input, Object::Conversion::kToNumber, bigint_handling)); |
| } |
| |
| TNode<Numeric> CodeStubAssembler::NonNumberToNumeric( |
| SloppyTNode<Context> context, SloppyTNode<HeapObject> input) { |
| Node* result = NonNumberToNumberOrNumeric(context, input, |
| Object::Conversion::kToNumeric); |
| CSA_SLOW_ASSERT(this, IsNumeric(result)); |
| return UncheckedCast<Numeric>(result); |
| } |
| |
| TNode<Number> CodeStubAssembler::ToNumber_Inline(SloppyTNode<Context> context, |
| SloppyTNode<Object> input) { |
| TVARIABLE(Number, var_result); |
| Label end(this), not_smi(this, Label::kDeferred); |
| |
| GotoIfNot(TaggedIsSmi(input), ¬_smi); |
| var_result = CAST(input); |
| Goto(&end); |
| |
| BIND(¬_smi); |
| { |
| var_result = |
| Select<Number>(IsHeapNumber(CAST(input)), [=] { return CAST(input); }, |
| [=] { |
| return CAST(CallBuiltin(Builtins::kNonNumberToNumber, |
| context, input)); |
| }); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::ToNumber(SloppyTNode<Context> context, |
| SloppyTNode<Object> input, |
| BigIntHandling bigint_handling) { |
| TVARIABLE(Number, var_result); |
| Label end(this); |
| |
| Label not_smi(this, Label::kDeferred); |
| GotoIfNot(TaggedIsSmi(input), ¬_smi); |
| TNode<Smi> input_smi = CAST(input); |
| var_result = input_smi; |
| Goto(&end); |
| |
| BIND(¬_smi); |
| { |
| Label not_heap_number(this, Label::kDeferred); |
| TNode<HeapObject> input_ho = CAST(input); |
| GotoIfNot(IsHeapNumber(input_ho), ¬_heap_number); |
| |
| TNode<HeapNumber> input_hn = CAST(input_ho); |
| var_result = input_hn; |
| Goto(&end); |
| |
| BIND(¬_heap_number); |
| { |
| var_result = NonNumberToNumber(context, input_ho, bigint_handling); |
| Goto(&end); |
| } |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| TNode<BigInt> CodeStubAssembler::ToBigInt(SloppyTNode<Context> context, |
| SloppyTNode<Object> input) { |
| TVARIABLE(BigInt, var_result); |
| Label if_bigint(this), done(this), if_throw(this); |
| |
| GotoIf(TaggedIsSmi(input), &if_throw); |
| GotoIf(IsBigInt(CAST(input)), &if_bigint); |
| var_result = CAST(CallRuntime(Runtime::kToBigInt, context, input)); |
| Goto(&done); |
| |
| BIND(&if_bigint); |
| var_result = CAST(input); |
| Goto(&done); |
| |
| BIND(&if_throw); |
| ThrowTypeError(context, MessageTemplate::kBigIntFromObject, input); |
| |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| void CodeStubAssembler::TaggedToNumeric(Node* context, Node* value, Label* done, |
| Variable* var_numeric) { |
| TaggedToNumeric(context, value, done, var_numeric, nullptr); |
| } |
| |
| void CodeStubAssembler::TaggedToNumericWithFeedback(Node* context, Node* value, |
| Label* done, |
| Variable* var_numeric, |
| Variable* var_feedback) { |
| DCHECK_NOT_NULL(var_feedback); |
| TaggedToNumeric(context, value, done, var_numeric, var_feedback); |
| } |
| |
| void CodeStubAssembler::TaggedToNumeric(Node* context, Node* value, Label* done, |
| Variable* var_numeric, |
| Variable* var_feedback) { |
| var_numeric->Bind(value); |
| Label if_smi(this), if_heapnumber(this), if_bigint(this), if_oddball(this); |
| GotoIf(TaggedIsSmi(value), &if_smi); |
| Node* map = LoadMap(value); |
| GotoIf(IsHeapNumberMap(map), &if_heapnumber); |
| Node* instance_type = LoadMapInstanceType(map); |
| GotoIf(IsBigIntInstanceType(instance_type), &if_bigint); |
| |
| // {value} is not a Numeric yet. |
| GotoIf(Word32Equal(instance_type, Int32Constant(ODDBALL_TYPE)), &if_oddball); |
| var_numeric->Bind(CallBuiltin(Builtins::kNonNumberToNumeric, context, value)); |
| OverwriteFeedback(var_feedback, BinaryOperationFeedback::kAny); |
| Goto(done); |
| |
| BIND(&if_smi); |
| OverwriteFeedback(var_feedback, BinaryOperationFeedback::kSignedSmall); |
| Goto(done); |
| |
| BIND(&if_heapnumber); |
| OverwriteFeedback(var_feedback, BinaryOperationFeedback::kNumber); |
| Goto(done); |
| |
| BIND(&if_bigint); |
| OverwriteFeedback(var_feedback, BinaryOperationFeedback::kBigInt); |
| Goto(done); |
| |
| BIND(&if_oddball); |
| OverwriteFeedback(var_feedback, BinaryOperationFeedback::kNumberOrOddball); |
| var_numeric->Bind(LoadObjectField(value, Oddball::kToNumberOffset)); |
| Goto(done); |
| } |
| |
| // ES#sec-touint32 |
| TNode<Number> CodeStubAssembler::ToUint32(SloppyTNode<Context> context, |
| SloppyTNode<Object> input) { |
| Node* const float_zero = Float64Constant(0.0); |
| Node* const float_two_32 = Float64Constant(static_cast<double>(1ULL << 32)); |
| |
| Label out(this); |
| |
| VARIABLE(var_result, MachineRepresentation::kTagged, input); |
| |
| // Early exit for positive smis. |
| { |
| // TODO(jgruber): This branch and the recheck below can be removed once we |
| // have a ToNumber with multiple exits. |
| Label next(this, Label::kDeferred); |
| Branch(TaggedIsPositiveSmi(input), &out, &next); |
| BIND(&next); |
| } |
| |
| Node* const number = ToNumber(context, input); |
| var_result.Bind(number); |
| |
| // Perhaps we have a positive smi now. |
| { |
| Label next(this, Label::kDeferred); |
| Branch(TaggedIsPositiveSmi(number), &out, &next); |
| BIND(&next); |
| } |
| |
| Label if_isnegativesmi(this), if_isheapnumber(this); |
| Branch(TaggedIsSmi(number), &if_isnegativesmi, &if_isheapnumber); |
| |
| BIND(&if_isnegativesmi); |
| { |
| Node* const uint32_value = SmiToInt32(number); |
| Node* float64_value = ChangeUint32ToFloat64(uint32_value); |
| var_result.Bind(AllocateHeapNumberWithValue(float64_value)); |
| Goto(&out); |
| } |
| |
| BIND(&if_isheapnumber); |
| { |
| Label return_zero(this); |
| Node* const value = LoadHeapNumberValue(number); |
| |
| { |
| // +-0. |
| Label next(this); |
| Branch(Float64Equal(value, float_zero), &return_zero, &next); |
| BIND(&next); |
| } |
| |
| { |
| // NaN. |
| Label next(this); |
| Branch(Float64Equal(value, value), &next, &return_zero); |
| BIND(&next); |
| } |
| |
| { |
| // +Infinity. |
| Label next(this); |
| Node* const positive_infinity = |
| Float64Constant(std::numeric_limits<double>::infinity()); |
| Branch(Float64Equal(value, positive_infinity), &return_zero, &next); |
| BIND(&next); |
| } |
| |
| { |
| // -Infinity. |
| Label next(this); |
| Node* const negative_infinity = |
| Float64Constant(-1.0 * std::numeric_limits<double>::infinity()); |
| Branch(Float64Equal(value, negative_infinity), &return_zero, &next); |
| BIND(&next); |
| } |
| |
| // * Let int be the mathematical value that is the same sign as number and |
| // whose magnitude is floor(abs(number)). |
| // * Let int32bit be int modulo 2^32. |
| // * Return int32bit. |
| { |
| Node* x = Float64Trunc(value); |
| x = Float64Mod(x, float_two_32); |
| x = Float64Add(x, float_two_32); |
| x = Float64Mod(x, float_two_32); |
| |
| Node* const result = ChangeFloat64ToTagged(x); |
| var_result.Bind(result); |
| Goto(&out); |
| } |
| |
| BIND(&return_zero); |
| { |
| var_result.Bind(SmiConstant(0)); |
| Goto(&out); |
| } |
| } |
| |
| BIND(&out); |
| return CAST(var_result.value()); |
| } |
| |
| TNode<String> CodeStubAssembler::ToString(SloppyTNode<Context> context, |
| SloppyTNode<Object> input) { |
| Label is_number(this); |
| Label runtime(this, Label::kDeferred), done(this); |
| VARIABLE(result, MachineRepresentation::kTagged); |
| GotoIf(TaggedIsSmi(input), &is_number); |
| |
| TNode<Map> input_map = LoadMap(CAST(input)); |
| TNode<Int32T> input_instance_type = LoadMapInstanceType(input_map); |
| |
| result.Bind(input); |
| GotoIf(IsStringInstanceType(input_instance_type), &done); |
| |
| Label not_heap_number(this); |
| Branch(IsHeapNumberMap(input_map), &is_number, ¬_heap_number); |
| |
| BIND(&is_number); |
| TNode<Number> number_input = CAST(input); |
| result.Bind(NumberToString(number_input)); |
| Goto(&done); |
| |
| BIND(¬_heap_number); |
| { |
| GotoIfNot(InstanceTypeEqual(input_instance_type, ODDBALL_TYPE), &runtime); |
| result.Bind(LoadObjectField(CAST(input), Oddball::kToStringOffset)); |
| Goto(&done); |
| } |
| |
| BIND(&runtime); |
| { |
| result.Bind(CallRuntime(Runtime::kToString, context, input)); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return CAST(result.value()); |
| } |
| |
| TNode<String> CodeStubAssembler::ToString_Inline(SloppyTNode<Context> context, |
| SloppyTNode<Object> input) { |
| VARIABLE(var_result, MachineRepresentation::kTagged, input); |
| Label stub_call(this, Label::kDeferred), out(this); |
| |
| GotoIf(TaggedIsSmi(input), &stub_call); |
| Branch(IsString(CAST(input)), &out, &stub_call); |
| |
| BIND(&stub_call); |
| var_result.Bind(CallBuiltin(Builtins::kToString, context, input)); |
| Goto(&out); |
| |
| BIND(&out); |
| return CAST(var_result.value()); |
| } |
| |
| Node* CodeStubAssembler::JSReceiverToPrimitive(Node* context, Node* input) { |
| Label if_isreceiver(this, Label::kDeferred), if_isnotreceiver(this); |
| VARIABLE(result, MachineRepresentation::kTagged); |
| Label done(this, &result); |
| |
| BranchIfJSReceiver(input, &if_isreceiver, &if_isnotreceiver); |
| |
| BIND(&if_isreceiver); |
| { |
| // Convert {input} to a primitive first passing Number hint. |
| Callable callable = CodeFactory::NonPrimitiveToPrimitive(isolate()); |
| result.Bind(CallStub(callable, context, input)); |
| Goto(&done); |
| } |
| |
| BIND(&if_isnotreceiver); |
| { |
| result.Bind(input); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<JSReceiver> CodeStubAssembler::ToObject(SloppyTNode<Context> context, |
| SloppyTNode<Object> input) { |
| return CAST(CallBuiltin(Builtins::kToObject, context, input)); |
| } |
| |
| TNode<JSReceiver> CodeStubAssembler::ToObject_Inline(TNode<Context> context, |
| TNode<Object> input) { |
| TVARIABLE(JSReceiver, result); |
| Label if_isreceiver(this), if_isnotreceiver(this, Label::kDeferred); |
| Label done(this); |
| |
| BranchIfJSReceiver(input, &if_isreceiver, &if_isnotreceiver); |
| |
| BIND(&if_isreceiver); |
| { |
| result = CAST(input); |
| Goto(&done); |
| } |
| |
| BIND(&if_isnotreceiver); |
| { |
| result = ToObject(context, input); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<Smi> CodeStubAssembler::ToSmiIndex(TNode<Context> context, |
| TNode<Object> input, |
| Label* range_error) { |
| TVARIABLE(Smi, result); |
| Label check_undefined(this), return_zero(this), defined(this), |
| negative_check(this), done(this); |
| |
| GotoIfNot(TaggedIsSmi(input), &check_undefined); |
| result = CAST(input); |
| Goto(&negative_check); |
| |
| BIND(&check_undefined); |
| Branch(IsUndefined(input), &return_zero, &defined); |
| |
| BIND(&defined); |
| TNode<Number> integer_input = |
| CAST(CallBuiltin(Builtins::kToInteger_TruncateMinusZero, context, input)); |
| GotoIfNot(TaggedIsSmi(integer_input), range_error); |
| result = CAST(integer_input); |
| Goto(&negative_check); |
| |
| BIND(&negative_check); |
| Branch(SmiLessThan(result.value(), SmiConstant(0)), range_error, &done); |
| |
| BIND(&return_zero); |
| result = SmiConstant(0); |
| Goto(&done); |
| |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<Smi> CodeStubAssembler::ToSmiLength(TNode<Context> context, |
| TNode<Object> input, |
| Label* range_error) { |
| TVARIABLE(Smi, result); |
| Label to_integer(this), negative_check(this), |
| heap_number_negative_check(this), return_zero(this), done(this); |
| |
| GotoIfNot(TaggedIsSmi(input), &to_integer); |
| result = CAST(input); |
| Goto(&negative_check); |
| |
| BIND(&to_integer); |
| { |
| TNode<Number> integer_input = CAST( |
| CallBuiltin(Builtins::kToInteger_TruncateMinusZero, context, input)); |
| GotoIfNot(TaggedIsSmi(integer_input), &heap_number_negative_check); |
| result = CAST(integer_input); |
| Goto(&negative_check); |
| |
| // integer_input can still be a negative HeapNumber here. |
| BIND(&heap_number_negative_check); |
| TNode<HeapNumber> heap_number_input = CAST(integer_input); |
| Branch(IsTrue(CallBuiltin(Builtins::kLessThan, context, heap_number_input, |
| SmiConstant(0))), |
| &return_zero, range_error); |
| } |
| |
| BIND(&negative_check); |
| Branch(SmiLessThan(result.value(), SmiConstant(0)), &return_zero, &done); |
| |
| BIND(&return_zero); |
| result = SmiConstant(0); |
| Goto(&done); |
| |
| BIND(&done); |
| return result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::ToLength_Inline(SloppyTNode<Context> context, |
| SloppyTNode<Object> input) { |
| TNode<Smi> smi_zero = SmiConstant(0); |
| return Select<Number>( |
| TaggedIsSmi(input), [=] { return SmiMax(CAST(input), smi_zero); }, |
| [=] { return CAST(CallBuiltin(Builtins::kToLength, context, input)); }); |
| } |
| |
| TNode<Number> CodeStubAssembler::ToInteger_Inline( |
| SloppyTNode<Context> context, SloppyTNode<Object> input, |
| ToIntegerTruncationMode mode) { |
| Builtins::Name builtin = (mode == kNoTruncation) |
| ? Builtins::kToInteger |
| : Builtins::kToInteger_TruncateMinusZero; |
| return Select<Number>( |
| TaggedIsSmi(input), [=] { return CAST(input); }, |
| [=] { return CAST(CallBuiltin(builtin, context, input)); }); |
| } |
| |
| TNode<Number> CodeStubAssembler::ToInteger(SloppyTNode<Context> context, |
| SloppyTNode<Object> input, |
| ToIntegerTruncationMode mode) { |
| // We might need to loop once for ToNumber conversion. |
| TVARIABLE(Object, var_arg, input); |
| Label loop(this, &var_arg), out(this); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| // Shared entry points. |
| Label return_zero(this, Label::kDeferred); |
| |
| // Load the current {arg} value. |
| TNode<Object> arg = var_arg.value(); |
| |
| // Check if {arg} is a Smi. |
| GotoIf(TaggedIsSmi(arg), &out); |
| |
| // Check if {arg} is a HeapNumber. |
| Label if_argisheapnumber(this), |
| if_argisnotheapnumber(this, Label::kDeferred); |
| Branch(IsHeapNumber(CAST(arg)), &if_argisheapnumber, |
| &if_argisnotheapnumber); |
| |
| BIND(&if_argisheapnumber); |
| { |
| TNode<HeapNumber> arg_hn = CAST(arg); |
| // Load the floating-point value of {arg}. |
| Node* arg_value = LoadHeapNumberValue(arg_hn); |
| |
| // Check if {arg} is NaN. |
| GotoIfNot(Float64Equal(arg_value, arg_value), &return_zero); |
| |
| // Truncate {arg} towards zero. |
| TNode<Float64T> value = Float64Trunc(arg_value); |
| |
| if (mode == kTruncateMinusZero) { |
| // Truncate -0.0 to 0. |
| GotoIf(Float64Equal(value, Float64Constant(0.0)), &return_zero); |
| } |
| |
| var_arg = ChangeFloat64ToTagged(value); |
| Goto(&out); |
| } |
| |
| BIND(&if_argisnotheapnumber); |
| { |
| // Need to convert {arg} to a Number first. |
| var_arg = UncheckedCast<Object>( |
| CallBuiltin(Builtins::kNonNumberToNumber, context, arg)); |
| Goto(&loop); |
| } |
| |
| BIND(&return_zero); |
| var_arg = SmiConstant(0); |
| Goto(&out); |
| } |
| |
| BIND(&out); |
| if (mode == kTruncateMinusZero) { |
| CSA_ASSERT(this, IsNumberNormalized(CAST(var_arg.value()))); |
| } |
| return CAST(var_arg.value()); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::DecodeWord32(SloppyTNode<Word32T> word32, |
| uint32_t shift, uint32_t mask) { |
| return UncheckedCast<Uint32T>(Word32Shr( |
| Word32And(word32, Int32Constant(mask)), static_cast<int>(shift))); |
| } |
| |
| TNode<UintPtrT> CodeStubAssembler::DecodeWord(SloppyTNode<WordT> word, |
| uint32_t shift, uint32_t mask) { |
| return Unsigned( |
| WordShr(WordAnd(word, IntPtrConstant(mask)), static_cast<int>(shift))); |
| } |
| |
| TNode<WordT> CodeStubAssembler::UpdateWord(TNode<WordT> word, |
| TNode<WordT> value, uint32_t shift, |
| uint32_t mask) { |
| TNode<WordT> encoded_value = WordShl(value, static_cast<int>(shift)); |
| TNode<IntPtrT> inverted_mask = IntPtrConstant(~static_cast<intptr_t>(mask)); |
| // Ensure the {value} fits fully in the mask. |
| CSA_ASSERT(this, WordEqual(WordAnd(encoded_value, inverted_mask), |
| IntPtrConstant(0))); |
| return WordOr(WordAnd(word, inverted_mask), encoded_value); |
| } |
| |
| void CodeStubAssembler::SetCounter(StatsCounter* counter, int value) { |
| if (FLAG_native_code_counters && counter->Enabled()) { |
| Node* counter_address = |
| ExternalConstant(ExternalReference::Create(counter)); |
| StoreNoWriteBarrier(MachineRepresentation::kWord32, counter_address, |
| Int32Constant(value)); |
| } |
| } |
| |
| void CodeStubAssembler::IncrementCounter(StatsCounter* counter, int delta) { |
| DCHECK_GT(delta, 0); |
| if (FLAG_native_code_counters && counter->Enabled()) { |
| Node* counter_address = |
| ExternalConstant(ExternalReference::Create(counter)); |
| Node* value = Load(MachineType::Int32(), counter_address); |
| value = Int32Add(value, Int32Constant(delta)); |
| StoreNoWriteBarrier(MachineRepresentation::kWord32, counter_address, value); |
| } |
| } |
| |
| void CodeStubAssembler::DecrementCounter(StatsCounter* counter, int delta) { |
| DCHECK_GT(delta, 0); |
| if (FLAG_native_code_counters && counter->Enabled()) { |
| Node* counter_address = |
| ExternalConstant(ExternalReference::Create(counter)); |
| Node* value = Load(MachineType::Int32(), counter_address); |
| value = Int32Sub(value, Int32Constant(delta)); |
| StoreNoWriteBarrier(MachineRepresentation::kWord32, counter_address, value); |
| } |
| } |
| |
| void CodeStubAssembler::Increment(Variable* variable, int value, |
| ParameterMode mode) { |
| DCHECK_IMPLIES(mode == INTPTR_PARAMETERS, |
| variable->rep() == MachineType::PointerRepresentation()); |
| DCHECK_IMPLIES(mode == SMI_PARAMETERS, |
| variable->rep() == MachineRepresentation::kTagged || |
| variable->rep() == MachineRepresentation::kTaggedSigned); |
| variable->Bind(IntPtrOrSmiAdd(variable->value(), |
| IntPtrOrSmiConstant(value, mode), mode)); |
| } |
| |
| void CodeStubAssembler::Use(Label* label) { |
| GotoIf(Word32Equal(Int32Constant(0), Int32Constant(1)), label); |
| } |
| |
| void CodeStubAssembler::TryToName(Node* key, Label* if_keyisindex, |
| Variable* var_index, Label* if_keyisunique, |
| Variable* var_unique, Label* if_bailout, |
| Label* if_notinternalized) { |
| DCHECK_EQ(MachineType::PointerRepresentation(), var_index->rep()); |
| DCHECK_EQ(MachineRepresentation::kTagged, var_unique->rep()); |
| Comment("TryToName"); |
| |
| Label if_hascachedindex(this), if_keyisnotindex(this), if_thinstring(this), |
| if_keyisother(this, Label::kDeferred); |
| // Handle Smi and HeapNumber keys. |
| var_index->Bind(TryToIntptr(key, &if_keyisnotindex)); |
| Goto(if_keyisindex); |
| |
| BIND(&if_keyisnotindex); |
| Node* key_map = LoadMap(key); |
| var_unique->Bind(key); |
| // Symbols are unique. |
| GotoIf(IsSymbolMap(key_map), if_keyisunique); |
| Node* key_instance_type = LoadMapInstanceType(key_map); |
| // Miss if |key| is not a String. |
| STATIC_ASSERT(FIRST_NAME_TYPE == FIRST_TYPE); |
| GotoIfNot(IsStringInstanceType(key_instance_type), &if_keyisother); |
| |
| // |key| is a String. Check if it has a cached array index. |
| Node* hash = LoadNameHashField(key); |
| GotoIf(IsClearWord32(hash, Name::kDoesNotContainCachedArrayIndexMask), |
| &if_hascachedindex); |
| // No cached array index. If the string knows that it contains an index, |
| // then it must be an uncacheable index. Handle this case in the runtime. |
| GotoIf(IsClearWord32(hash, Name::kIsNotArrayIndexMask), if_bailout); |
| // Check if we have a ThinString. |
| GotoIf(InstanceTypeEqual(key_instance_type, THIN_STRING_TYPE), |
| &if_thinstring); |
| GotoIf(InstanceTypeEqual(key_instance_type, THIN_ONE_BYTE_STRING_TYPE), |
| &if_thinstring); |
| // Finally, check if |key| is internalized. |
| STATIC_ASSERT(kNotInternalizedTag != 0); |
| GotoIf(IsSetWord32(key_instance_type, kIsNotInternalizedMask), |
| if_notinternalized != nullptr ? if_notinternalized : if_bailout); |
| Goto(if_keyisunique); |
| |
| BIND(&if_thinstring); |
| var_unique->Bind(LoadObjectField(key, ThinString::kActualOffset)); |
| Goto(if_keyisunique); |
| |
| BIND(&if_hascachedindex); |
| var_index->Bind(DecodeWordFromWord32<Name::ArrayIndexValueBits>(hash)); |
| Goto(if_keyisindex); |
| |
| BIND(&if_keyisother); |
| GotoIfNot(InstanceTypeEqual(key_instance_type, ODDBALL_TYPE), if_bailout); |
| var_unique->Bind(LoadObjectField(key, Oddball::kToStringOffset)); |
| Goto(if_keyisunique); |
| } |
| |
| void CodeStubAssembler::TryInternalizeString( |
| Node* string, Label* if_index, Variable* var_index, Label* if_internalized, |
| Variable* var_internalized, Label* if_not_internalized, Label* if_bailout) { |
| DCHECK(var_index->rep() == MachineType::PointerRepresentation()); |
| DCHECK_EQ(var_internalized->rep(), MachineRepresentation::kTagged); |
| CSA_SLOW_ASSERT(this, IsString(string)); |
| Node* function = |
| ExternalConstant(ExternalReference::try_internalize_string_function()); |
| Node* const isolate_ptr = |
| ExternalConstant(ExternalReference::isolate_address(isolate())); |
| Node* result = |
| CallCFunction2(MachineType::AnyTagged(), MachineType::Pointer(), |
| MachineType::AnyTagged(), function, isolate_ptr, string); |
| Label internalized(this); |
| GotoIf(TaggedIsNotSmi(result), &internalized); |
| Node* word_result = SmiUntag(result); |
| GotoIf(WordEqual(word_result, IntPtrConstant(ResultSentinel::kNotFound)), |
| if_not_internalized); |
| GotoIf(WordEqual(word_result, IntPtrConstant(ResultSentinel::kUnsupported)), |
| if_bailout); |
| var_index->Bind(word_result); |
| Goto(if_index); |
| |
| BIND(&internalized); |
| var_internalized->Bind(result); |
| Goto(if_internalized); |
| } |
| |
| template <typename Dictionary> |
| TNode<IntPtrT> CodeStubAssembler::EntryToIndex(TNode<IntPtrT> entry, |
| int field_index) { |
| TNode<IntPtrT> entry_index = |
| IntPtrMul(entry, IntPtrConstant(Dictionary::kEntrySize)); |
| return IntPtrAdd(entry_index, IntPtrConstant(Dictionary::kElementsStartIndex + |
| field_index)); |
| } |
| |
| TNode<MaybeObject> CodeStubAssembler::LoadDescriptorArrayElement( |
| TNode<DescriptorArray> object, Node* index, int additional_offset) { |
| return LoadArrayElement(object, DescriptorArray::kHeaderSize, index, |
| additional_offset); |
| } |
| |
| TNode<Name> CodeStubAssembler::LoadKeyByKeyIndex( |
| TNode<DescriptorArray> container, TNode<IntPtrT> key_index) { |
| return CAST(LoadDescriptorArrayElement(container, key_index, 0)); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::LoadDetailsByKeyIndex( |
| TNode<DescriptorArray> container, TNode<IntPtrT> key_index) { |
| const int kKeyToDetails = |
| DescriptorArray::ToDetailsIndex(0) - DescriptorArray::ToKeyIndex(0); |
| return Unsigned( |
| LoadAndUntagToWord32ArrayElement(container, DescriptorArray::kHeaderSize, |
| key_index, kKeyToDetails * kTaggedSize)); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadValueByKeyIndex( |
| TNode<DescriptorArray> container, TNode<IntPtrT> key_index) { |
| const int kKeyToValue = |
| DescriptorArray::ToValueIndex(0) - DescriptorArray::ToKeyIndex(0); |
| return CAST(LoadDescriptorArrayElement(container, key_index, |
| kKeyToValue * kTaggedSize)); |
| } |
| |
| TNode<MaybeObject> CodeStubAssembler::LoadFieldTypeByKeyIndex( |
| TNode<DescriptorArray> container, TNode<IntPtrT> key_index) { |
| const int kKeyToValue = |
| DescriptorArray::ToValueIndex(0) - DescriptorArray::ToKeyIndex(0); |
| return LoadDescriptorArrayElement(container, key_index, |
| kKeyToValue * kTaggedSize); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::DescriptorEntryToIndex( |
| TNode<IntPtrT> descriptor_entry) { |
| return IntPtrMul(descriptor_entry, |
| IntPtrConstant(DescriptorArray::kEntrySize)); |
| } |
| |
| TNode<Name> CodeStubAssembler::LoadKeyByDescriptorEntry( |
| TNode<DescriptorArray> container, TNode<IntPtrT> descriptor_entry) { |
| return CAST(LoadDescriptorArrayElement( |
| container, DescriptorEntryToIndex(descriptor_entry), |
| DescriptorArray::ToKeyIndex(0) * kTaggedSize)); |
| } |
| |
| TNode<Name> CodeStubAssembler::LoadKeyByDescriptorEntry( |
| TNode<DescriptorArray> container, int descriptor_entry) { |
| return CAST(LoadDescriptorArrayElement( |
| container, IntPtrConstant(0), |
| DescriptorArray::ToKeyIndex(descriptor_entry) * kTaggedSize)); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::LoadDetailsByDescriptorEntry( |
| TNode<DescriptorArray> container, TNode<IntPtrT> descriptor_entry) { |
| return Unsigned(LoadAndUntagToWord32ArrayElement( |
| container, DescriptorArray::kHeaderSize, |
| DescriptorEntryToIndex(descriptor_entry), |
| DescriptorArray::ToDetailsIndex(0) * kTaggedSize)); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::LoadDetailsByDescriptorEntry( |
| TNode<DescriptorArray> container, int descriptor_entry) { |
| return Unsigned(LoadAndUntagToWord32ArrayElement( |
| container, DescriptorArray::kHeaderSize, IntPtrConstant(0), |
| DescriptorArray::ToDetailsIndex(descriptor_entry) * kTaggedSize)); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadValueByDescriptorEntry( |
| TNode<DescriptorArray> container, int descriptor_entry) { |
| return CAST(LoadDescriptorArrayElement( |
| container, IntPtrConstant(0), |
| DescriptorArray::ToValueIndex(descriptor_entry) * kTaggedSize)); |
| } |
| |
| TNode<MaybeObject> CodeStubAssembler::LoadFieldTypeByDescriptorEntry( |
| TNode<DescriptorArray> container, TNode<IntPtrT> descriptor_entry) { |
| return LoadDescriptorArrayElement( |
| container, DescriptorEntryToIndex(descriptor_entry), |
| DescriptorArray::ToValueIndex(0) * kTaggedSize); |
| } |
| |
| template TNode<IntPtrT> CodeStubAssembler::EntryToIndex<NameDictionary>( |
| TNode<IntPtrT>, int); |
| template TNode<IntPtrT> CodeStubAssembler::EntryToIndex<GlobalDictionary>( |
| TNode<IntPtrT>, int); |
| template TNode<IntPtrT> CodeStubAssembler::EntryToIndex<NumberDictionary>( |
| TNode<IntPtrT>, int); |
| |
| // This must be kept in sync with HashTableBase::ComputeCapacity(). |
| TNode<IntPtrT> CodeStubAssembler::HashTableComputeCapacity( |
| TNode<IntPtrT> at_least_space_for) { |
| TNode<IntPtrT> capacity = IntPtrRoundUpToPowerOfTwo32( |
| IntPtrAdd(at_least_space_for, WordShr(at_least_space_for, 1))); |
| return IntPtrMax(capacity, IntPtrConstant(HashTableBase::kMinCapacity)); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::IntPtrMax(SloppyTNode<IntPtrT> left, |
| SloppyTNode<IntPtrT> right) { |
| intptr_t left_constant; |
| intptr_t right_constant; |
| if (ToIntPtrConstant(left, left_constant) && |
| ToIntPtrConstant(right, right_constant)) { |
| return IntPtrConstant(std::max(left_constant, right_constant)); |
| } |
| return SelectConstant<IntPtrT>(IntPtrGreaterThanOrEqual(left, right), left, |
| right); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::IntPtrMin(SloppyTNode<IntPtrT> left, |
| SloppyTNode<IntPtrT> right) { |
| intptr_t left_constant; |
| intptr_t right_constant; |
| if (ToIntPtrConstant(left, left_constant) && |
| ToIntPtrConstant(right, right_constant)) { |
| return IntPtrConstant(std::min(left_constant, right_constant)); |
| } |
| return SelectConstant<IntPtrT>(IntPtrLessThanOrEqual(left, right), left, |
| right); |
| } |
| |
| template <> |
| TNode<HeapObject> CodeStubAssembler::LoadName<NameDictionary>( |
| TNode<HeapObject> key) { |
| CSA_ASSERT(this, Word32Or(IsTheHole(key), IsName(key))); |
| return key; |
| } |
| |
| template <> |
| TNode<HeapObject> CodeStubAssembler::LoadName<GlobalDictionary>( |
| TNode<HeapObject> key) { |
| TNode<PropertyCell> property_cell = CAST(key); |
| return CAST(LoadObjectField(property_cell, PropertyCell::kNameOffset)); |
| } |
| |
| template <typename Dictionary> |
| void CodeStubAssembler::NameDictionaryLookup( |
| TNode<Dictionary> dictionary, TNode<Name> unique_name, Label* if_found, |
| TVariable<IntPtrT>* var_name_index, Label* if_not_found, int inlined_probes, |
| LookupMode mode) { |
| static_assert(std::is_same<Dictionary, NameDictionary>::value || |
| std::is_same<Dictionary, GlobalDictionary>::value, |
| "Unexpected NameDictionary"); |
| DCHECK_EQ(MachineType::PointerRepresentation(), var_name_index->rep()); |
| DCHECK_IMPLIES(mode == kFindInsertionIndex, |
| inlined_probes == 0 && if_found == nullptr); |
| Comment("NameDictionaryLookup"); |
| |
| TNode<IntPtrT> capacity = SmiUntag(GetCapacity<Dictionary>(dictionary)); |
| TNode<WordT> mask = IntPtrSub(capacity, IntPtrConstant(1)); |
| TNode<WordT> hash = ChangeUint32ToWord(LoadNameHash(unique_name)); |
| |
| // See Dictionary::FirstProbe(). |
| TNode<IntPtrT> count = IntPtrConstant(0); |
| TNode<IntPtrT> entry = Signed(WordAnd(hash, mask)); |
| Node* undefined = UndefinedConstant(); |
| |
| for (int i = 0; i < inlined_probes; i++) { |
| TNode<IntPtrT> index = EntryToIndex<Dictionary>(entry); |
| *var_name_index = index; |
| |
| TNode<HeapObject> current = |
| CAST(UnsafeLoadFixedArrayElement(dictionary, index)); |
| GotoIf(WordEqual(current, undefined), if_not_found); |
| current = LoadName<Dictionary>(current); |
| GotoIf(WordEqual(current, unique_name), if_found); |
| |
| // See Dictionary::NextProbe(). |
| count = IntPtrConstant(i + 1); |
| entry = Signed(WordAnd(IntPtrAdd(entry, count), mask)); |
| } |
| if (mode == kFindInsertionIndex) { |
| // Appease the variable merging algorithm for "Goto(&loop)" below. |
| *var_name_index = IntPtrConstant(0); |
| } |
| |
| TVARIABLE(IntPtrT, var_count, count); |
| TVARIABLE(IntPtrT, var_entry, entry); |
| Variable* loop_vars[] = {&var_count, &var_entry, var_name_index}; |
| Label loop(this, 3, loop_vars); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| TNode<IntPtrT> entry = var_entry.value(); |
| |
| TNode<IntPtrT> index = EntryToIndex<Dictionary>(entry); |
| *var_name_index = index; |
| |
| TNode<HeapObject> current = CAST(LoadFixedArrayElement(dictionary, index)); |
| GotoIf(WordEqual(current, undefined), if_not_found); |
| if (mode == kFindExisting) { |
| current = LoadName<Dictionary>(current); |
| GotoIf(WordEqual(current, unique_name), if_found); |
| } else { |
| DCHECK_EQ(kFindInsertionIndex, mode); |
| GotoIf(WordEqual(current, TheHoleConstant()), if_not_found); |
| } |
| |
| // See Dictionary::NextProbe(). |
| Increment(&var_count); |
| entry = Signed(WordAnd(IntPtrAdd(entry, var_count.value()), mask)); |
| |
| var_entry = entry; |
| Goto(&loop); |
| } |
| } |
| |
| // Instantiate template methods to workaround GCC compilation issue. |
| template void CodeStubAssembler::NameDictionaryLookup<NameDictionary>( |
| TNode<NameDictionary>, TNode<Name>, Label*, TVariable<IntPtrT>*, Label*, |
| int, LookupMode); |
| template void CodeStubAssembler::NameDictionaryLookup<GlobalDictionary>( |
| TNode<GlobalDictionary>, TNode<Name>, Label*, TVariable<IntPtrT>*, Label*, |
| int, LookupMode); |
| |
| Node* CodeStubAssembler::ComputeUnseededHash(Node* key) { |
| // See v8::internal::ComputeUnseededHash() |
| Node* hash = TruncateIntPtrToInt32(key); |
| hash = Int32Add(Word32Xor(hash, Int32Constant(0xFFFFFFFF)), |
| Word32Shl(hash, Int32Constant(15))); |
| hash = Word32Xor(hash, Word32Shr(hash, Int32Constant(12))); |
| hash = Int32Add(hash, Word32Shl(hash, Int32Constant(2))); |
| hash = Word32Xor(hash, Word32Shr(hash, Int32Constant(4))); |
| hash = Int32Mul(hash, Int32Constant(2057)); |
| hash = Word32Xor(hash, Word32Shr(hash, Int32Constant(16))); |
| return Word32And(hash, Int32Constant(0x3FFFFFFF)); |
| } |
| |
| Node* CodeStubAssembler::ComputeSeededHash(Node* key) { |
| Node* const function_addr = |
| ExternalConstant(ExternalReference::compute_integer_hash()); |
| Node* const isolate_ptr = |
| ExternalConstant(ExternalReference::isolate_address(isolate())); |
| |
| MachineType type_ptr = MachineType::Pointer(); |
| MachineType type_uint32 = MachineType::Uint32(); |
| |
| Node* const result = |
| CallCFunction2(type_uint32, type_ptr, type_uint32, function_addr, |
| isolate_ptr, TruncateIntPtrToInt32(key)); |
| return result; |
| } |
| |
| void CodeStubAssembler::NumberDictionaryLookup( |
| TNode<NumberDictionary> dictionary, TNode<IntPtrT> intptr_index, |
| Label* if_found, TVariable<IntPtrT>* var_entry, Label* if_not_found) { |
| CSA_ASSERT(this, IsNumberDictionary(dictionary)); |
| DCHECK_EQ(MachineType::PointerRepresentation(), var_entry->rep()); |
| Comment("NumberDictionaryLookup"); |
| |
| TNode<IntPtrT> capacity = SmiUntag(GetCapacity<NumberDictionary>(dictionary)); |
| TNode<WordT> mask = IntPtrSub(capacity, IntPtrConstant(1)); |
| |
| TNode<WordT> hash = ChangeUint32ToWord(ComputeSeededHash(intptr_index)); |
| Node* key_as_float64 = RoundIntPtrToFloat64(intptr_index); |
| |
| // See Dictionary::FirstProbe(). |
| TNode<IntPtrT> count = IntPtrConstant(0); |
| TNode<IntPtrT> entry = Signed(WordAnd(hash, mask)); |
| |
| Node* undefined = UndefinedConstant(); |
| Node* the_hole = TheHoleConstant(); |
| |
| TVARIABLE(IntPtrT, var_count, count); |
| Variable* loop_vars[] = {&var_count, var_entry}; |
| Label loop(this, 2, loop_vars); |
| *var_entry = entry; |
| Goto(&loop); |
| BIND(&loop); |
| { |
| TNode<IntPtrT> entry = var_entry->value(); |
| |
| TNode<IntPtrT> index = EntryToIndex<NumberDictionary>(entry); |
| Node* current = UnsafeLoadFixedArrayElement(dictionary, index); |
| GotoIf(WordEqual(current, undefined), if_not_found); |
| Label next_probe(this); |
| { |
| Label if_currentissmi(this), if_currentisnotsmi(this); |
| Branch(TaggedIsSmi(current), &if_currentissmi, &if_currentisnotsmi); |
| BIND(&if_currentissmi); |
| { |
| Node* current_value = SmiUntag(current); |
| Branch(WordEqual(current_value, intptr_index), if_found, &next_probe); |
| } |
| BIND(&if_currentisnotsmi); |
| { |
| GotoIf(WordEqual(current, the_hole), &next_probe); |
| // Current must be the Number. |
| Node* current_value = LoadHeapNumberValue(current); |
| Branch(Float64Equal(current_value, key_as_float64), if_found, |
| &next_probe); |
| } |
| } |
| |
| BIND(&next_probe); |
| // See Dictionary::NextProbe(). |
| Increment(&var_count); |
| entry = Signed(WordAnd(IntPtrAdd(entry, var_count.value()), mask)); |
| |
| *var_entry = entry; |
| Goto(&loop); |
| } |
| } |
| |
| TNode<Object> CodeStubAssembler::BasicLoadNumberDictionaryElement( |
| TNode<NumberDictionary> dictionary, TNode<IntPtrT> intptr_index, |
| Label* not_data, Label* if_hole) { |
| TVARIABLE(IntPtrT, var_entry); |
| Label if_found(this); |
| NumberDictionaryLookup(dictionary, intptr_index, &if_found, &var_entry, |
| if_hole); |
| BIND(&if_found); |
| |
| // Check that the value is a data property. |
| TNode<IntPtrT> index = EntryToIndex<NumberDictionary>(var_entry.value()); |
| TNode<Uint32T> details = |
| LoadDetailsByKeyIndex<NumberDictionary>(dictionary, index); |
| TNode<Uint32T> kind = DecodeWord32<PropertyDetails::KindField>(details); |
| // TODO(jkummerow): Support accessors without missing? |
| GotoIfNot(Word32Equal(kind, Int32Constant(kData)), not_data); |
| // Finally, load the value. |
| return LoadValueByKeyIndex<NumberDictionary>(dictionary, index); |
| } |
| |
| void CodeStubAssembler::BasicStoreNumberDictionaryElement( |
| TNode<NumberDictionary> dictionary, TNode<IntPtrT> intptr_index, |
| TNode<Object> value, Label* not_data, Label* if_hole, Label* read_only) { |
| TVARIABLE(IntPtrT, var_entry); |
| Label if_found(this); |
| NumberDictionaryLookup(dictionary, intptr_index, &if_found, &var_entry, |
| if_hole); |
| BIND(&if_found); |
| |
| // Check that the value is a data property. |
| TNode<IntPtrT> index = EntryToIndex<NumberDictionary>(var_entry.value()); |
| TNode<Uint32T> details = |
| LoadDetailsByKeyIndex<NumberDictionary>(dictionary, index); |
| TNode<Uint32T> kind = DecodeWord32<PropertyDetails::KindField>(details); |
| // TODO(jkummerow): Support accessors without missing? |
| GotoIfNot(Word32Equal(kind, Int32Constant(kData)), not_data); |
| |
| // Check that the property is writeable. |
| GotoIf(IsSetWord32(details, PropertyDetails::kAttributesReadOnlyMask), |
| read_only); |
| |
| // Finally, store the value. |
| StoreValueByKeyIndex<NumberDictionary>(dictionary, index, value); |
| } |
| |
| template <class Dictionary> |
| void CodeStubAssembler::FindInsertionEntry(TNode<Dictionary> dictionary, |
| TNode<Name> key, |
| TVariable<IntPtrT>* var_key_index) { |
| UNREACHABLE(); |
| } |
| |
| template <> |
| void CodeStubAssembler::FindInsertionEntry<NameDictionary>( |
| TNode<NameDictionary> dictionary, TNode<Name> key, |
| TVariable<IntPtrT>* var_key_index) { |
| Label done(this); |
| NameDictionaryLookup<NameDictionary>(dictionary, key, nullptr, var_key_index, |
| &done, 0, kFindInsertionIndex); |
| BIND(&done); |
| } |
| |
| template <class Dictionary> |
| void CodeStubAssembler::InsertEntry(TNode<Dictionary> dictionary, |
| TNode<Name> key, TNode<Object> value, |
| TNode<IntPtrT> index, |
| TNode<Smi> enum_index) { |
| UNREACHABLE(); // Use specializations instead. |
| } |
| |
| template <> |
| void CodeStubAssembler::InsertEntry<NameDictionary>( |
| TNode<NameDictionary> dictionary, TNode<Name> name, TNode<Object> value, |
| TNode<IntPtrT> index, TNode<Smi> enum_index) { |
| // Store name and value. |
| StoreFixedArrayElement(dictionary, index, name); |
| StoreValueByKeyIndex<NameDictionary>(dictionary, index, value); |
| |
| // Prepare details of the new property. |
| PropertyDetails d(kData, NONE, PropertyCellType::kNoCell); |
| enum_index = |
| SmiShl(enum_index, PropertyDetails::DictionaryStorageField::kShift); |
| // We OR over the actual index below, so we expect the initial value to be 0. |
| DCHECK_EQ(0, d.dictionary_index()); |
| TVARIABLE(Smi, var_details, SmiOr(SmiConstant(d.AsSmi()), enum_index)); |
| |
| // Private names must be marked non-enumerable. |
| Label not_private(this, &var_details); |
| GotoIfNot(IsPrivateSymbol(name), ¬_private); |
| TNode<Smi> dont_enum = |
| SmiShl(SmiConstant(DONT_ENUM), PropertyDetails::AttributesField::kShift); |
| var_details = SmiOr(var_details.value(), dont_enum); |
| Goto(¬_private); |
| BIND(¬_private); |
| |
| // Finally, store the details. |
| StoreDetailsByKeyIndex<NameDictionary>(dictionary, index, |
| var_details.value()); |
| } |
| |
| template <> |
| void CodeStubAssembler::InsertEntry<GlobalDictionary>( |
| TNode<GlobalDictionary> dictionary, TNode<Name> key, TNode<Object> value, |
| TNode<IntPtrT> index, TNode<Smi> enum_index) { |
| UNIMPLEMENTED(); |
| } |
| |
| template <class Dictionary> |
| void CodeStubAssembler::Add(TNode<Dictionary> dictionary, TNode<Name> key, |
| TNode<Object> value, Label* bailout) { |
| CSA_ASSERT(this, Word32BinaryNot(IsEmptyPropertyDictionary(dictionary))); |
| TNode<Smi> capacity = GetCapacity<Dictionary>(dictionary); |
| TNode<Smi> nof = GetNumberOfElements<Dictionary>(dictionary); |
| TNode<Smi> new_nof = SmiAdd(nof, SmiConstant(1)); |
| // Require 33% to still be free after adding additional_elements. |
| // Computing "x + (x >> 1)" on a Smi x does not return a valid Smi! |
| // But that's OK here because it's only used for a comparison. |
| TNode<Smi> required_capacity_pseudo_smi = SmiAdd(new_nof, SmiShr(new_nof, 1)); |
| GotoIf(SmiBelow(capacity, required_capacity_pseudo_smi), bailout); |
| // Require rehashing if more than 50% of free elements are deleted elements. |
| TNode<Smi> deleted = GetNumberOfDeletedElements<Dictionary>(dictionary); |
| CSA_ASSERT(this, SmiAbove(capacity, new_nof)); |
| TNode<Smi> half_of_free_elements = SmiShr(SmiSub(capacity, new_nof), 1); |
| GotoIf(SmiAbove(deleted, half_of_free_elements), bailout); |
| |
| TNode<Smi> enum_index = GetNextEnumerationIndex<Dictionary>(dictionary); |
| TNode<Smi> new_enum_index = SmiAdd(enum_index, SmiConstant(1)); |
| TNode<Smi> max_enum_index = |
| SmiConstant(PropertyDetails::DictionaryStorageField::kMax); |
| GotoIf(SmiAbove(new_enum_index, max_enum_index), bailout); |
| |
| // No more bailouts after this point. |
| // Operations from here on can have side effects. |
| |
| SetNextEnumerationIndex<Dictionary>(dictionary, new_enum_index); |
| SetNumberOfElements<Dictionary>(dictionary, new_nof); |
| |
| TVARIABLE(IntPtrT, var_key_index); |
| FindInsertionEntry<Dictionary>(dictionary, key, &var_key_index); |
| InsertEntry<Dictionary>(dictionary, key, value, var_key_index.value(), |
| enum_index); |
| } |
| |
| template void CodeStubAssembler::Add<NameDictionary>(TNode<NameDictionary>, |
| TNode<Name>, TNode<Object>, |
| Label*); |
| |
| template <typename Array> |
| void CodeStubAssembler::LookupLinear(TNode<Name> unique_name, |
| TNode<Array> array, |
| TNode<Uint32T> number_of_valid_entries, |
| Label* if_found, |
| TVariable<IntPtrT>* var_name_index, |
| Label* if_not_found) { |
| static_assert(std::is_base_of<FixedArray, Array>::value || |
| std::is_base_of<WeakFixedArray, Array>::value || |
| std::is_base_of<DescriptorArray, Array>::value, |
| "T must be a descendant of FixedArray or a WeakFixedArray"); |
| Comment("LookupLinear"); |
| TNode<IntPtrT> first_inclusive = IntPtrConstant(Array::ToKeyIndex(0)); |
| TNode<IntPtrT> factor = IntPtrConstant(Array::kEntrySize); |
| TNode<IntPtrT> last_exclusive = IntPtrAdd( |
| first_inclusive, |
| IntPtrMul(ChangeInt32ToIntPtr(number_of_valid_entries), factor)); |
| |
| BuildFastLoop(last_exclusive, first_inclusive, |
| [=](SloppyTNode<IntPtrT> name_index) { |
| TNode<MaybeObject> element = |
| LoadArrayElement(array, Array::kHeaderSize, name_index); |
| TNode<Name> candidate_name = CAST(element); |
| *var_name_index = name_index; |
| GotoIf(WordEqual(candidate_name, unique_name), if_found); |
| }, |
| -Array::kEntrySize, INTPTR_PARAMETERS, IndexAdvanceMode::kPre); |
| Goto(if_not_found); |
| } |
| |
| template <> |
| TNode<Uint32T> CodeStubAssembler::NumberOfEntries<DescriptorArray>( |
| TNode<DescriptorArray> descriptors) { |
| return Unsigned(LoadNumberOfDescriptors(descriptors)); |
| } |
| |
| template <> |
| TNode<Uint32T> CodeStubAssembler::NumberOfEntries<TransitionArray>( |
| TNode<TransitionArray> transitions) { |
| TNode<IntPtrT> length = LoadAndUntagWeakFixedArrayLength(transitions); |
| return Select<Uint32T>( |
| UintPtrLessThan(length, IntPtrConstant(TransitionArray::kFirstIndex)), |
| [=] { return Unsigned(Int32Constant(0)); }, |
| [=] { |
| return Unsigned(LoadAndUntagToWord32ArrayElement( |
| transitions, WeakFixedArray::kHeaderSize, |
| IntPtrConstant(TransitionArray::kTransitionLengthIndex))); |
| }); |
| } |
| |
| template <typename Array> |
| TNode<IntPtrT> CodeStubAssembler::EntryIndexToIndex( |
| TNode<Uint32T> entry_index) { |
| TNode<Int32T> entry_size = Int32Constant(Array::kEntrySize); |
| TNode<Word32T> index = Int32Mul(entry_index, entry_size); |
| return ChangeInt32ToIntPtr(index); |
| } |
| |
| template <typename Array> |
| TNode<IntPtrT> CodeStubAssembler::ToKeyIndex(TNode<Uint32T> entry_index) { |
| return IntPtrAdd(IntPtrConstant(Array::ToKeyIndex(0)), |
| EntryIndexToIndex<Array>(entry_index)); |
| } |
| |
| template TNode<IntPtrT> CodeStubAssembler::ToKeyIndex<DescriptorArray>( |
| TNode<Uint32T>); |
| template TNode<IntPtrT> CodeStubAssembler::ToKeyIndex<TransitionArray>( |
| TNode<Uint32T>); |
| |
| template <> |
| TNode<Uint32T> CodeStubAssembler::GetSortedKeyIndex<DescriptorArray>( |
| TNode<DescriptorArray> descriptors, TNode<Uint32T> descriptor_number) { |
| TNode<Uint32T> details = |
| DescriptorArrayGetDetails(descriptors, descriptor_number); |
| return DecodeWord32<PropertyDetails::DescriptorPointer>(details); |
| } |
| |
| template <> |
| TNode<Uint32T> CodeStubAssembler::GetSortedKeyIndex<TransitionArray>( |
| TNode<TransitionArray> transitions, TNode<Uint32T> transition_number) { |
| return transition_number; |
| } |
| |
| template <typename Array> |
| TNode<Name> CodeStubAssembler::GetKey(TNode<Array> array, |
| TNode<Uint32T> entry_index) { |
| static_assert(std::is_base_of<TransitionArray, Array>::value || |
| std::is_base_of<DescriptorArray, Array>::value, |
| "T must be a descendant of DescriptorArray or TransitionArray"); |
| const int key_offset = Array::ToKeyIndex(0) * kTaggedSize; |
| TNode<MaybeObject> element = |
| LoadArrayElement(array, Array::kHeaderSize, |
| EntryIndexToIndex<Array>(entry_index), key_offset); |
| return CAST(element); |
| } |
| |
| template TNode<Name> CodeStubAssembler::GetKey<DescriptorArray>( |
| TNode<DescriptorArray>, TNode<Uint32T>); |
| template TNode<Name> CodeStubAssembler::GetKey<TransitionArray>( |
| TNode<TransitionArray>, TNode<Uint32T>); |
| |
| TNode<Uint32T> CodeStubAssembler::DescriptorArrayGetDetails( |
| TNode<DescriptorArray> descriptors, TNode<Uint32T> descriptor_number) { |
| const int details_offset = DescriptorArray::ToDetailsIndex(0) * kTaggedSize; |
| return Unsigned(LoadAndUntagToWord32ArrayElement( |
| descriptors, DescriptorArray::kHeaderSize, |
| EntryIndexToIndex<DescriptorArray>(descriptor_number), details_offset)); |
| } |
| |
| template <typename Array> |
| void CodeStubAssembler::LookupBinary(TNode<Name> unique_name, |
| TNode<Array> array, |
| TNode<Uint32T> number_of_valid_entries, |
| Label* if_found, |
| TVariable<IntPtrT>* var_name_index, |
| Label* if_not_found) { |
| Comment("LookupBinary"); |
| TVARIABLE(Uint32T, var_low, Unsigned(Int32Constant(0))); |
| TNode<Uint32T> limit = |
| Unsigned(Int32Sub(NumberOfEntries<Array>(array), Int32Constant(1))); |
| TVARIABLE(Uint32T, var_high, limit); |
| TNode<Uint32T> hash = LoadNameHashField(unique_name); |
| CSA_ASSERT(this, Word32NotEqual(hash, Int32Constant(0))); |
| |
| // Assume non-empty array. |
| CSA_ASSERT(this, Uint32LessThanOrEqual(var_low.value(), var_high.value())); |
| |
| Label binary_loop(this, {&var_high, &var_low}); |
| Goto(&binary_loop); |
| BIND(&binary_loop); |
| { |
| // mid = low + (high - low) / 2 (to avoid overflow in "(low + high) / 2"). |
| TNode<Uint32T> mid = Unsigned( |
| Int32Add(var_low.value(), |
| Word32Shr(Int32Sub(var_high.value(), var_low.value()), 1))); |
| // mid_name = array->GetSortedKey(mid). |
| TNode<Uint32T> sorted_key_index = GetSortedKeyIndex<Array>(array, mid); |
| TNode<Name> mid_name = GetKey<Array>(array, sorted_key_index); |
| |
| TNode<Uint32T> mid_hash = LoadNameHashField(mid_name); |
| |
| Label mid_greater(this), mid_less(this), merge(this); |
| Branch(Uint32GreaterThanOrEqual(mid_hash, hash), &mid_greater, &mid_less); |
| BIND(&mid_greater); |
| { |
| var_high = mid; |
| Goto(&merge); |
| } |
| BIND(&mid_less); |
| { |
| var_low = Unsigned(Int32Add(mid, Int32Constant(1))); |
| Goto(&merge); |
| } |
| BIND(&merge); |
| GotoIf(Word32NotEqual(var_low.value(), var_high.value()), &binary_loop); |
| } |
| |
| Label scan_loop(this, &var_low); |
| Goto(&scan_loop); |
| BIND(&scan_loop); |
| { |
| GotoIf(Int32GreaterThan(var_low.value(), limit), if_not_found); |
| |
| TNode<Uint32T> sort_index = |
| GetSortedKeyIndex<Array>(array, var_low.value()); |
| TNode<Name> current_name = GetKey<Array>(array, sort_index); |
| TNode<Uint32T> current_hash = LoadNameHashField(current_name); |
| GotoIf(Word32NotEqual(current_hash, hash), if_not_found); |
| Label next(this); |
| GotoIf(WordNotEqual(current_name, unique_name), &next); |
| GotoIf(Uint32GreaterThanOrEqual(sort_index, number_of_valid_entries), |
| if_not_found); |
| *var_name_index = ToKeyIndex<Array>(sort_index); |
| Goto(if_found); |
| |
| BIND(&next); |
| var_low = Unsigned(Int32Add(var_low.value(), Int32Constant(1))); |
| Goto(&scan_loop); |
| } |
| } |
| |
| void CodeStubAssembler::DescriptorArrayForEach( |
| VariableList& variable_list, TNode<Uint32T> start_descriptor, |
| TNode<Uint32T> end_descriptor, const ForEachDescriptorBodyFunction& body) { |
| TNode<IntPtrT> start_index = ToKeyIndex<DescriptorArray>(start_descriptor); |
| TNode<IntPtrT> end_index = ToKeyIndex<DescriptorArray>(end_descriptor); |
| |
| BuildFastLoop(variable_list, start_index, end_index, |
| [=](Node* index) { |
| TNode<IntPtrT> descriptor_key_index = |
| TNode<IntPtrT>::UncheckedCast(index); |
| body(descriptor_key_index); |
| }, |
| DescriptorArray::kEntrySize, INTPTR_PARAMETERS, |
| IndexAdvanceMode::kPost); |
| } |
| |
| void CodeStubAssembler::ForEachEnumerableOwnProperty( |
| TNode<Context> context, TNode<Map> map, TNode<JSObject> object, |
| ForEachEnumerationMode mode, const ForEachKeyValueFunction& body, |
| Label* bailout) { |
| TNode<Int32T> type = LoadMapInstanceType(map); |
| TNode<Uint32T> bit_field3 = EnsureOnlyHasSimpleProperties(map, type, bailout); |
| |
| TNode<DescriptorArray> descriptors = LoadMapDescriptors(map); |
| TNode<Uint32T> nof_descriptors = |
| DecodeWord32<Map::NumberOfOwnDescriptorsBits>(bit_field3); |
| |
| TVARIABLE(BoolT, var_stable, Int32TrueConstant()); |
| |
| TVARIABLE(BoolT, var_has_symbol, Int32FalseConstant()); |
| // false - iterate only string properties, true - iterate only symbol |
| // properties |
| TVARIABLE(BoolT, var_name_filter, Int32FalseConstant()); |
| VariableList list({&var_stable, &var_has_symbol, &var_name_filter}, zone()); |
| Label descriptor_array_loop(this, |
| {&var_stable, &var_has_symbol, &var_name_filter}); |
| |
| Goto(&descriptor_array_loop); |
| BIND(&descriptor_array_loop); |
| |
| DescriptorArrayForEach( |
| list, Unsigned(Int32Constant(0)), nof_descriptors, |
| [=, &var_stable, &var_has_symbol, |
| &var_name_filter](TNode<IntPtrT> descriptor_key_index) { |
| TNode<Name> next_key = |
| LoadKeyByKeyIndex(descriptors, descriptor_key_index); |
| |
| TVARIABLE(Object, var_value, SmiConstant(0)); |
| Label callback(this), next_iteration(this); |
| |
| if (mode == kEnumerationOrder) { |
| // |next_key| is either a string or a symbol |
| // Skip strings or symbols depending on var_name_filter value. |
| Label if_string(this), if_symbol(this), if_name_ok(this); |
| |
| Branch(IsSymbol(next_key), &if_symbol, &if_string); |
| BIND(&if_symbol); |
| { |
| var_has_symbol = Int32TrueConstant(); |
| // Process symbol property when |var_name_filer| is true. |
| Branch(var_name_filter.value(), &if_name_ok, &next_iteration); |
| } |
| BIND(&if_string); |
| { |
| CSA_ASSERT(this, IsString(next_key)); |
| // Process string property when |var_name_filer| is false. |
| Branch(var_name_filter.value(), &next_iteration, &if_name_ok); |
| } |
| BIND(&if_name_ok); |
| } |
| { |
| TVARIABLE(Map, var_map); |
| TVARIABLE(HeapObject, var_meta_storage); |
| TVARIABLE(IntPtrT, var_entry); |
| TVARIABLE(Uint32T, var_details); |
| Label if_found(this); |
| |
| Label if_found_fast(this), if_found_dict(this); |
| |
| Label if_stable(this), if_not_stable(this); |
| Branch(var_stable.value(), &if_stable, &if_not_stable); |
| BIND(&if_stable); |
| { |
| // Directly decode from the descriptor array if |object| did not |
| // change shape. |
| var_map = map; |
| var_meta_storage = descriptors; |
| var_entry = Signed(descriptor_key_index); |
| Goto(&if_found_fast); |
| } |
| BIND(&if_not_stable); |
| { |
| // If the map did change, do a slower lookup. We are still |
| // guaranteed that the object has a simple shape, and that the key |
| // is a name. |
| var_map = LoadMap(object); |
| TryLookupPropertyInSimpleObject( |
| object, var_map.value(), next_key, &if_found_fast, |
| &if_found_dict, &var_meta_storage, &var_entry, &next_iteration); |
| } |
| |
| BIND(&if_found_fast); |
| { |
| TNode<DescriptorArray> descriptors = CAST(var_meta_storage.value()); |
| TNode<IntPtrT> name_index = var_entry.value(); |
| |
| // Skip non-enumerable properties. |
| var_details = LoadDetailsByKeyIndex(descriptors, name_index); |
| GotoIf(IsSetWord32(var_details.value(), |
| PropertyDetails::kAttributesDontEnumMask), |
| &next_iteration); |
| |
| LoadPropertyFromFastObject(object, var_map.value(), descriptors, |
| name_index, var_details.value(), |
| &var_value); |
| Goto(&if_found); |
| } |
| BIND(&if_found_dict); |
| { |
| TNode<NameDictionary> dictionary = CAST(var_meta_storage.value()); |
| TNode<IntPtrT> entry = var_entry.value(); |
| |
| TNode<Uint32T> details = |
| LoadDetailsByKeyIndex<NameDictionary>(dictionary, entry); |
| // Skip non-enumerable properties. |
| GotoIf( |
| IsSetWord32(details, PropertyDetails::kAttributesDontEnumMask), |
| &next_iteration); |
| |
| var_details = details; |
| var_value = LoadValueByKeyIndex<NameDictionary>(dictionary, entry); |
| Goto(&if_found); |
| } |
| |
| // Here we have details and value which could be an accessor. |
| BIND(&if_found); |
| { |
| Label slow_load(this, Label::kDeferred); |
| |
| var_value = CallGetterIfAccessor(var_value.value(), |
| var_details.value(), context, |
| object, &slow_load, kCallJSGetter); |
| Goto(&callback); |
| |
| BIND(&slow_load); |
| var_value = |
| CallRuntime(Runtime::kGetProperty, context, object, next_key); |
| Goto(&callback); |
| |
| BIND(&callback); |
| body(next_key, var_value.value()); |
| |
| // Check if |object| is still stable, i.e. we can proceed using |
| // property details from preloaded |descriptors|. |
| var_stable = |
| Select<BoolT>(var_stable.value(), |
| [=] { return WordEqual(LoadMap(object), map); }, |
| [=] { return Int32FalseConstant(); }); |
| |
| Goto(&next_iteration); |
| } |
| } |
| BIND(&next_iteration); |
| }); |
| |
| if (mode == kEnumerationOrder) { |
| Label done(this); |
| GotoIf(var_name_filter.value(), &done); |
| GotoIfNot(var_has_symbol.value(), &done); |
| // All string properties are processed, now process symbol properties. |
| var_name_filter = Int32TrueConstant(); |
| Goto(&descriptor_array_loop); |
| |
| BIND(&done); |
| } |
| } |
| |
| void CodeStubAssembler::DescriptorLookup( |
| SloppyTNode<Name> unique_name, SloppyTNode<DescriptorArray> descriptors, |
| SloppyTNode<Uint32T> bitfield3, Label* if_found, |
| TVariable<IntPtrT>* var_name_index, Label* if_not_found) { |
| Comment("DescriptorArrayLookup"); |
| TNode<Uint32T> nof = DecodeWord32<Map::NumberOfOwnDescriptorsBits>(bitfield3); |
| Lookup<DescriptorArray>(unique_name, descriptors, nof, if_found, |
| var_name_index, if_not_found); |
| } |
| |
| void CodeStubAssembler::TransitionLookup( |
| SloppyTNode<Name> unique_name, SloppyTNode<TransitionArray> transitions, |
| Label* if_found, TVariable<IntPtrT>* var_name_index, Label* if_not_found) { |
| Comment("TransitionArrayLookup"); |
| TNode<Uint32T> number_of_valid_transitions = |
| NumberOfEntries<TransitionArray>(transitions); |
| Lookup<TransitionArray>(unique_name, transitions, number_of_valid_transitions, |
| if_found, var_name_index, if_not_found); |
| } |
| |
| template <typename Array> |
| void CodeStubAssembler::Lookup(TNode<Name> unique_name, TNode<Array> array, |
| TNode<Uint32T> number_of_valid_entries, |
| Label* if_found, |
| TVariable<IntPtrT>* var_name_index, |
| Label* if_not_found) { |
| Comment("ArrayLookup"); |
| if (!number_of_valid_entries) { |
| number_of_valid_entries = NumberOfEntries(array); |
| } |
| GotoIf(Word32Equal(number_of_valid_entries, Int32Constant(0)), if_not_found); |
| Label linear_search(this), binary_search(this); |
| const int kMaxElementsForLinearSearch = 32; |
| Branch(Uint32LessThanOrEqual(number_of_valid_entries, |
| Int32Constant(kMaxElementsForLinearSearch)), |
| &linear_search, &binary_search); |
| BIND(&linear_search); |
| { |
| LookupLinear<Array>(unique_name, array, number_of_valid_entries, if_found, |
| var_name_index, if_not_found); |
| } |
| BIND(&binary_search); |
| { |
| LookupBinary<Array>(unique_name, array, number_of_valid_entries, if_found, |
| var_name_index, if_not_found); |
| } |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsSimpleObjectMap(TNode<Map> map) { |
| uint32_t mask = |
| Map::HasNamedInterceptorBit::kMask | Map::IsAccessCheckNeededBit::kMask; |
| // !IsSpecialReceiverType && !IsNamedInterceptor && !IsAccessCheckNeeded |
| return Select<BoolT>( |
| IsSpecialReceiverInstanceType(LoadMapInstanceType(map)), |
| [=] { return Int32FalseConstant(); }, |
| [=] { return IsClearWord32(LoadMapBitField(map), mask); }); |
| } |
| |
| void CodeStubAssembler::TryLookupPropertyInSimpleObject( |
| TNode<JSObject> object, TNode<Map> map, TNode<Name> unique_name, |
| Label* if_found_fast, Label* if_found_dict, |
| TVariable<HeapObject>* var_meta_storage, TVariable<IntPtrT>* var_name_index, |
| Label* if_not_found) { |
| CSA_ASSERT(this, IsSimpleObjectMap(map)); |
| |
| TNode<Uint32T> bit_field3 = LoadMapBitField3(map); |
| Label if_isfastmap(this), if_isslowmap(this); |
| Branch(IsSetWord32<Map::IsDictionaryMapBit>(bit_field3), &if_isslowmap, |
| &if_isfastmap); |
| BIND(&if_isfastmap); |
| { |
| TNode<DescriptorArray> descriptors = LoadMapDescriptors(map); |
| *var_meta_storage = descriptors; |
| |
| DescriptorLookup(unique_name, descriptors, bit_field3, if_found_fast, |
| var_name_index, if_not_found); |
| } |
| BIND(&if_isslowmap); |
| { |
| TNode<NameDictionary> dictionary = CAST(LoadSlowProperties(object)); |
| *var_meta_storage = dictionary; |
| |
| NameDictionaryLookup<NameDictionary>(dictionary, unique_name, if_found_dict, |
| var_name_index, if_not_found); |
| } |
| } |
| |
| void CodeStubAssembler::TryLookupProperty( |
| SloppyTNode<JSObject> object, SloppyTNode<Map> map, |
| SloppyTNode<Int32T> instance_type, SloppyTNode<Name> unique_name, |
| Label* if_found_fast, Label* if_found_dict, Label* if_found_global, |
| TVariable<HeapObject>* var_meta_storage, TVariable<IntPtrT>* var_name_index, |
| Label* if_not_found, Label* if_bailout) { |
| Label if_objectisspecial(this); |
| GotoIf(IsSpecialReceiverInstanceType(instance_type), &if_objectisspecial); |
| |
| TryLookupPropertyInSimpleObject(object, map, unique_name, if_found_fast, |
| if_found_dict, var_meta_storage, |
| var_name_index, if_not_found); |
| |
| BIND(&if_objectisspecial); |
| { |
| // Handle global object here and bailout for other special objects. |
| GotoIfNot(InstanceTypeEqual(instance_type, JS_GLOBAL_OBJECT_TYPE), |
| if_bailout); |
| |
| // Handle interceptors and access checks in runtime. |
| TNode<Int32T> bit_field = LoadMapBitField(map); |
| int mask = |
| Map::HasNamedInterceptorBit::kMask | Map::IsAccessCheckNeededBit::kMask; |
| GotoIf(IsSetWord32(bit_field, mask), if_bailout); |
| |
| TNode<GlobalDictionary> dictionary = CAST(LoadSlowProperties(object)); |
| *var_meta_storage = dictionary; |
| |
| NameDictionaryLookup<GlobalDictionary>( |
| dictionary, unique_name, if_found_global, var_name_index, if_not_found); |
| } |
| } |
| |
| void CodeStubAssembler::TryHasOwnProperty(Node* object, Node* map, |
| Node* instance_type, |
| Node* unique_name, Label* if_found, |
| Label* if_not_found, |
| Label* if_bailout) { |
| Comment("TryHasOwnProperty"); |
| TVARIABLE(HeapObject, var_meta_storage); |
| TVARIABLE(IntPtrT, var_name_index); |
| |
| Label if_found_global(this); |
| TryLookupProperty(object, map, instance_type, unique_name, if_found, if_found, |
| &if_found_global, &var_meta_storage, &var_name_index, |
| if_not_found, if_bailout); |
| |
| BIND(&if_found_global); |
| { |
| VARIABLE(var_value, MachineRepresentation::kTagged); |
| VARIABLE(var_details, MachineRepresentation::kWord32); |
| // Check if the property cell is not deleted. |
| LoadPropertyFromGlobalDictionary(var_meta_storage.value(), |
| var_name_index.value(), &var_value, |
| &var_details, if_not_found); |
| Goto(if_found); |
| } |
| } |
| |
| Node* CodeStubAssembler::GetMethod(Node* context, Node* object, |
| Handle<Name> name, |
| Label* if_null_or_undefined) { |
| Node* method = GetProperty(context, object, name); |
| |
| GotoIf(IsUndefined(method), if_null_or_undefined); |
| GotoIf(IsNull(method), if_null_or_undefined); |
| |
| return method; |
| } |
| |
| TNode<Object> CodeStubAssembler::GetIteratorMethod( |
| TNode<Context> context, TNode<HeapObject> heap_obj, |
| Label* if_iteratorundefined) { |
| return CAST(GetMethod(context, heap_obj, |
| isolate()->factory()->iterator_symbol(), |
| if_iteratorundefined)); |
| } |
| |
| void CodeStubAssembler::LoadPropertyFromFastObject( |
| Node* object, Node* map, TNode<DescriptorArray> descriptors, |
| Node* name_index, Variable* var_details, Variable* var_value) { |
| DCHECK_EQ(MachineRepresentation::kWord32, var_details->rep()); |
| DCHECK_EQ(MachineRepresentation::kTagged, var_value->rep()); |
| |
| Node* details = |
| LoadDetailsByKeyIndex(descriptors, UncheckedCast<IntPtrT>(name_index)); |
| var_details->Bind(details); |
| |
| LoadPropertyFromFastObject(object, map, descriptors, name_index, details, |
| var_value); |
| } |
| |
| void CodeStubAssembler::LoadPropertyFromFastObject( |
| Node* object, Node* map, TNode<DescriptorArray> descriptors, |
| Node* name_index, Node* details, Variable* var_value) { |
| Comment("[ LoadPropertyFromFastObject"); |
| |
| Node* location = DecodeWord32<PropertyDetails::LocationField>(details); |
| |
| Label if_in_field(this), if_in_descriptor(this), done(this); |
| Branch(Word32Equal(location, Int32Constant(kField)), &if_in_field, |
| &if_in_descriptor); |
| BIND(&if_in_field); |
| { |
| Node* field_index = |
| DecodeWordFromWord32<PropertyDetails::FieldIndexField>(details); |
| Node* representation = |
| DecodeWord32<PropertyDetails::RepresentationField>(details); |
| |
| field_index = |
| IntPtrAdd(field_index, LoadMapInobjectPropertiesStartInWords(map)); |
| Node* instance_size_in_words = LoadMapInstanceSizeInWords(map); |
| |
| Label if_inobject(this), if_backing_store(this); |
| VARIABLE(var_double_value, MachineRepresentation::kFloat64); |
| Label rebox_double(this, &var_double_value); |
| Branch(UintPtrLessThan(field_index, instance_size_in_words), &if_inobject, |
| &if_backing_store); |
| BIND(&if_inobject); |
| { |
| Comment("if_inobject"); |
| Node* field_offset = TimesTaggedSize(field_index); |
| |
| Label if_double(this), if_tagged(this); |
| Branch(Word32NotEqual(representation, |
| Int32Constant(Representation::kDouble)), |
| &if_tagged, &if_double); |
| BIND(&if_tagged); |
| { |
| var_value->Bind(LoadObjectField(object, field_offset)); |
| Goto(&done); |
| } |
| BIND(&if_double); |
| { |
| if (FLAG_unbox_double_fields) { |
| var_double_value.Bind( |
| LoadObjectField(object, field_offset, MachineType::Float64())); |
| } else { |
| Node* mutable_heap_number = LoadObjectField(object, field_offset); |
| var_double_value.Bind(LoadHeapNumberValue(mutable_heap_number)); |
| } |
| Goto(&rebox_double); |
| } |
| } |
| BIND(&if_backing_store); |
| { |
| Comment("if_backing_store"); |
| TNode<HeapObject> properties = LoadFastProperties(object); |
| field_index = IntPtrSub(field_index, instance_size_in_words); |
| Node* value = LoadPropertyArrayElement(CAST(properties), field_index); |
| |
| Label if_double(this), if_tagged(this); |
| Branch(Word32NotEqual(representation, |
| Int32Constant(Representation::kDouble)), |
| &if_tagged, &if_double); |
| BIND(&if_tagged); |
| { |
| var_value->Bind(value); |
| Goto(&done); |
| } |
| BIND(&if_double); |
| { |
| var_double_value.Bind(LoadHeapNumberValue(value)); |
| Goto(&rebox_double); |
| } |
| } |
| BIND(&rebox_double); |
| { |
| Comment("rebox_double"); |
| Node* heap_number = AllocateHeapNumberWithValue(var_double_value.value()); |
| var_value->Bind(heap_number); |
| Goto(&done); |
| } |
| } |
| BIND(&if_in_descriptor); |
| { |
| var_value->Bind( |
| LoadValueByKeyIndex(descriptors, UncheckedCast<IntPtrT>(name_index))); |
| Goto(&done); |
| } |
| BIND(&done); |
| |
| Comment("] LoadPropertyFromFastObject"); |
| } |
| |
| void CodeStubAssembler::LoadPropertyFromNameDictionary(Node* dictionary, |
| Node* name_index, |
| Variable* var_details, |
| Variable* var_value) { |
| Comment("LoadPropertyFromNameDictionary"); |
| CSA_ASSERT(this, IsNameDictionary(dictionary)); |
| |
| var_details->Bind( |
| LoadDetailsByKeyIndex<NameDictionary>(dictionary, name_index)); |
| var_value->Bind(LoadValueByKeyIndex<NameDictionary>(dictionary, name_index)); |
| |
| Comment("] LoadPropertyFromNameDictionary"); |
| } |
| |
| void CodeStubAssembler::LoadPropertyFromGlobalDictionary(Node* dictionary, |
| Node* name_index, |
| Variable* var_details, |
| Variable* var_value, |
| Label* if_deleted) { |
| Comment("[ LoadPropertyFromGlobalDictionary"); |
| CSA_ASSERT(this, IsGlobalDictionary(dictionary)); |
| |
| Node* property_cell = LoadFixedArrayElement(CAST(dictionary), name_index); |
| CSA_ASSERT(this, IsPropertyCell(property_cell)); |
| |
| Node* value = LoadObjectField(property_cell, PropertyCell::kValueOffset); |
| GotoIf(WordEqual(value, TheHoleConstant()), if_deleted); |
| |
| var_value->Bind(value); |
| |
| Node* details = LoadAndUntagToWord32ObjectField(property_cell, |
| PropertyCell::kDetailsOffset); |
| var_details->Bind(details); |
| |
| Comment("] LoadPropertyFromGlobalDictionary"); |
| } |
| |
| // |value| is the property backing store's contents, which is either a value |
| // or an accessor pair, as specified by |details|. |
| // Returns either the original value, or the result of the getter call. |
| TNode<Object> CodeStubAssembler::CallGetterIfAccessor( |
| Node* value, Node* details, Node* context, Node* receiver, |
| Label* if_bailout, GetOwnPropertyMode mode) { |
| VARIABLE(var_value, MachineRepresentation::kTagged, value); |
| Label done(this), if_accessor_info(this, Label::kDeferred); |
| |
| Node* kind = DecodeWord32<PropertyDetails::KindField>(details); |
| GotoIf(Word32Equal(kind, Int32Constant(kData)), &done); |
| |
| // Accessor case. |
| GotoIfNot(IsAccessorPair(value), &if_accessor_info); |
| |
| // AccessorPair case. |
| { |
| if (mode == kCallJSGetter) { |
| Node* accessor_pair = value; |
| Node* getter = |
| LoadObjectField(accessor_pair, AccessorPair::kGetterOffset); |
| Node* getter_map = LoadMap(getter); |
| Node* instance_type = LoadMapInstanceType(getter_map); |
| // FunctionTemplateInfo getters are not supported yet. |
| GotoIf(InstanceTypeEqual(instance_type, FUNCTION_TEMPLATE_INFO_TYPE), |
| if_bailout); |
| |
| // Return undefined if the {getter} is not callable. |
| var_value.Bind(UndefinedConstant()); |
| GotoIfNot(IsCallableMap(getter_map), &done); |
| |
| // Call the accessor. |
| Callable callable = CodeFactory::Call(isolate()); |
| Node* result = CallJS(callable, context, getter, receiver); |
| var_value.Bind(result); |
| } |
| Goto(&done); |
| } |
| |
| // AccessorInfo case. |
| BIND(&if_accessor_info); |
| { |
| Node* accessor_info = value; |
| CSA_ASSERT(this, IsAccessorInfo(value)); |
| CSA_ASSERT(this, TaggedIsNotSmi(receiver)); |
| Label if_array(this), if_function(this), if_value(this); |
| |
| // Dispatch based on {receiver} instance type. |
| Node* receiver_map = LoadMap(receiver); |
| Node* receiver_instance_type = LoadMapInstanceType(receiver_map); |
| GotoIf(IsJSArrayInstanceType(receiver_instance_type), &if_array); |
| GotoIf(IsJSFunctionInstanceType(receiver_instance_type), &if_function); |
| Branch(IsJSValueInstanceType(receiver_instance_type), &if_value, |
| if_bailout); |
| |
| // JSArray AccessorInfo case. |
| BIND(&if_array); |
| { |
| // We only deal with the "length" accessor on JSArray. |
| GotoIfNot(IsLengthString( |
| LoadObjectField(accessor_info, AccessorInfo::kNameOffset)), |
| if_bailout); |
| var_value.Bind(LoadJSArrayLength(receiver)); |
| Goto(&done); |
| } |
| |
| // JSFunction AccessorInfo case. |
| BIND(&if_function); |
| { |
| // We only deal with the "prototype" accessor on JSFunction here. |
| GotoIfNot(IsPrototypeString( |
| LoadObjectField(accessor_info, AccessorInfo::kNameOffset)), |
| if_bailout); |
| |
| GotoIfPrototypeRequiresRuntimeLookup(CAST(receiver), CAST(receiver_map), |
| if_bailout); |
| var_value.Bind(LoadJSFunctionPrototype(receiver, if_bailout)); |
| Goto(&done); |
| } |
| |
| // JSValue AccessorInfo case. |
| BIND(&if_value); |
| { |
| // We only deal with the "length" accessor on JSValue string wrappers. |
| GotoIfNot(IsLengthString( |
| LoadObjectField(accessor_info, AccessorInfo::kNameOffset)), |
| if_bailout); |
| Node* receiver_value = LoadJSValueValue(receiver); |
| GotoIfNot(TaggedIsNotSmi(receiver_value), if_bailout); |
| GotoIfNot(IsString(receiver_value), if_bailout); |
| var_value.Bind(LoadStringLengthAsSmi(receiver_value)); |
| Goto(&done); |
| } |
| } |
| |
| BIND(&done); |
| return UncheckedCast<Object>(var_value.value()); |
| } |
| |
| void CodeStubAssembler::TryGetOwnProperty( |
| Node* context, Node* receiver, Node* object, Node* map, Node* instance_type, |
| Node* unique_name, Label* if_found_value, Variable* var_value, |
| Label* if_not_found, Label* if_bailout) { |
| TryGetOwnProperty(context, receiver, object, map, instance_type, unique_name, |
| if_found_value, var_value, nullptr, nullptr, if_not_found, |
| if_bailout, kCallJSGetter); |
| } |
| |
| void CodeStubAssembler::TryGetOwnProperty( |
| Node* context, Node* receiver, Node* object, Node* map, Node* instance_type, |
| Node* unique_name, Label* if_found_value, Variable* var_value, |
| Variable* var_details, Variable* var_raw_value, Label* if_not_found, |
| Label* if_bailout, GetOwnPropertyMode mode) { |
| DCHECK_EQ(MachineRepresentation::kTagged, var_value->rep()); |
| Comment("TryGetOwnProperty"); |
| |
| TVARIABLE(HeapObject, var_meta_storage); |
| TVARIABLE(IntPtrT, var_entry); |
| |
| Label if_found_fast(this), if_found_dict(this), if_found_global(this); |
| |
| VARIABLE(local_var_details, MachineRepresentation::kWord32); |
| if (!var_details) { |
| var_details = &local_var_details; |
| } |
| Label if_found(this); |
| |
| TryLookupProperty(object, map, instance_type, unique_name, &if_found_fast, |
| &if_found_dict, &if_found_global, &var_meta_storage, |
| &var_entry, if_not_found, if_bailout); |
| BIND(&if_found_fast); |
| { |
| TNode<DescriptorArray> descriptors = CAST(var_meta_storage.value()); |
| Node* name_index = var_entry.value(); |
| |
| LoadPropertyFromFastObject(object, map, descriptors, name_index, |
| var_details, var_value); |
| Goto(&if_found); |
| } |
| BIND(&if_found_dict); |
| { |
| Node* dictionary = var_meta_storage.value(); |
| Node* entry = var_entry.value(); |
| LoadPropertyFromNameDictionary(dictionary, entry, var_details, var_value); |
| Goto(&if_found); |
| } |
| BIND(&if_found_global); |
| { |
| Node* dictionary = var_meta_storage.value(); |
| Node* entry = var_entry.value(); |
| |
| LoadPropertyFromGlobalDictionary(dictionary, entry, var_details, var_value, |
| if_not_found); |
| Goto(&if_found); |
| } |
| // Here we have details and value which could be an accessor. |
| BIND(&if_found); |
| { |
| // TODO(ishell): Execute C++ accessor in case of accessor info |
| if (var_raw_value) { |
| var_raw_value->Bind(var_value->value()); |
| } |
| Node* value = CallGetterIfAccessor(var_value->value(), var_details->value(), |
| context, receiver, if_bailout, mode); |
| var_value->Bind(value); |
| Goto(if_found_value); |
| } |
| } |
| |
| void CodeStubAssembler::TryLookupElement(Node* object, Node* map, |
| SloppyTNode<Int32T> instance_type, |
| SloppyTNode<IntPtrT> intptr_index, |
| Label* if_found, Label* if_absent, |
| Label* if_not_found, |
| Label* if_bailout) { |
| // Handle special objects in runtime. |
| GotoIf(IsSpecialReceiverInstanceType(instance_type), if_bailout); |
| |
| Node* elements_kind = LoadMapElementsKind(map); |
| |
| // TODO(verwaest): Support other elements kinds as well. |
| Label if_isobjectorsmi(this), if_isdouble(this), if_isdictionary(this), |
| if_isfaststringwrapper(this), if_isslowstringwrapper(this), if_oob(this), |
| if_typedarray(this); |
| // clang-format off |
| int32_t values[] = { |
| // Handled by {if_isobjectorsmi}. |
| PACKED_SMI_ELEMENTS, HOLEY_SMI_ELEMENTS, PACKED_ELEMENTS, |
| HOLEY_ELEMENTS, |
| // Handled by {if_isdouble}. |
| PACKED_DOUBLE_ELEMENTS, HOLEY_DOUBLE_ELEMENTS, |
| // Handled by {if_isdictionary}. |
| DICTIONARY_ELEMENTS, |
| // Handled by {if_isfaststringwrapper}. |
| FAST_STRING_WRAPPER_ELEMENTS, |
| // Handled by {if_isslowstringwrapper}. |
| SLOW_STRING_WRAPPER_ELEMENTS, |
| // Handled by {if_not_found}. |
| NO_ELEMENTS, |
| // Handled by {if_typed_array}. |
| UINT8_ELEMENTS, |
| INT8_ELEMENTS, |
| UINT16_ELEMENTS, |
| INT16_ELEMENTS, |
| UINT32_ELEMENTS, |
| INT32_ELEMENTS, |
| FLOAT32_ELEMENTS, |
| FLOAT64_ELEMENTS, |
| UINT8_CLAMPED_ELEMENTS, |
| BIGUINT64_ELEMENTS, |
| BIGINT64_ELEMENTS, |
| }; |
| Label* labels[] = { |
| &if_isobjectorsmi, &if_isobjectorsmi, &if_isobjectorsmi, |
| &if_isobjectorsmi, |
| &if_isdouble, &if_isdouble, |
| &if_isdictionary, |
| &if_isfaststringwrapper, |
| &if_isslowstringwrapper, |
| if_not_found, |
| &if_typedarray, |
| &if_typedarray, |
| &if_typedarray, |
| &if_typedarray, |
| &if_typedarray, |
| &if_typedarray, |
| &if_typedarray, |
| &if_typedarray, |
| &if_typedarray, |
| &if_typedarray, |
| &if_typedarray, |
| }; |
| // clang-format on |
| STATIC_ASSERT(arraysize(values) == arraysize(labels)); |
| Switch(elements_kind, if_bailout, values, labels, arraysize(values)); |
| |
| BIND(&if_isobjectorsmi); |
| { |
| TNode<FixedArray> elements = CAST(LoadElements(object)); |
| TNode<IntPtrT> length = LoadAndUntagFixedArrayBaseLength(elements); |
| |
| GotoIfNot(UintPtrLessThan(intptr_index, length), &if_oob); |
| |
| TNode<Object> element = UnsafeLoadFixedArrayElement(elements, intptr_index); |
| TNode<Oddball> the_hole = TheHoleConstant(); |
| Branch(WordEqual(element, the_hole), if_not_found, if_found); |
| } |
| BIND(&if_isdouble); |
| { |
| TNode<FixedArrayBase> elements = LoadElements(object); |
| TNode<IntPtrT> length = LoadAndUntagFixedArrayBaseLength(elements); |
| |
| GotoIfNot(UintPtrLessThan(intptr_index, length), &if_oob); |
| |
| // Check if the element is a double hole, but don't load it. |
| LoadFixedDoubleArrayElement(CAST(elements), intptr_index, |
| MachineType::None(), 0, INTPTR_PARAMETERS, |
| if_not_found); |
| Goto(if_found); |
| } |
| BIND(&if_isdictionary); |
| { |
| // Negative keys must be converted to property names. |
| GotoIf(IntPtrLessThan(intptr_index, IntPtrConstant(0)), if_bailout); |
| |
| TVARIABLE(IntPtrT, var_entry); |
| TNode<NumberDictionary> elements = CAST(LoadElements(object)); |
| NumberDictionaryLookup(elements, intptr_index, if_found, &var_entry, |
| if_not_found); |
| } |
| BIND(&if_isfaststringwrapper); |
| { |
| CSA_ASSERT(this, HasInstanceType(object, JS_VALUE_TYPE)); |
| Node* string = LoadJSValueValue(object); |
| CSA_ASSERT(this, IsString(string)); |
| Node* length = LoadStringLengthAsWord(string); |
| GotoIf(UintPtrLessThan(intptr_index, length), if_found); |
| Goto(&if_isobjectorsmi); |
| } |
| BIND(&if_isslowstringwrapper); |
| { |
| CSA_ASSERT(this, HasInstanceType(object, JS_VALUE_TYPE)); |
| Node* string = LoadJSValueValue(object); |
| CSA_ASSERT(this, IsString(string)); |
| Node* length = LoadStringLengthAsWord(string); |
| GotoIf(UintPtrLessThan(intptr_index, length), if_found); |
| Goto(&if_isdictionary); |
| } |
| BIND(&if_typedarray); |
| { |
| Node* buffer = LoadObjectField(object, JSArrayBufferView::kBufferOffset); |
| GotoIf(IsDetachedBuffer(buffer), if_absent); |
| |
| Node* length = SmiUntag(LoadJSTypedArrayLength(CAST(object))); |
| Branch(UintPtrLessThan(intptr_index, length), if_found, if_absent); |
| } |
| BIND(&if_oob); |
| { |
| // Positive OOB indices mean "not found", negative indices must be |
| // converted to property names. |
| GotoIf(IntPtrLessThan(intptr_index, IntPtrConstant(0)), if_bailout); |
| Goto(if_not_found); |
| } |
| } |
| |
| void CodeStubAssembler::BranchIfMaybeSpecialIndex(TNode<String> name_string, |
| Label* if_maybe_special_index, |
| Label* if_not_special_index) { |
| // TODO(cwhan.tunz): Implement fast cases more. |
| |
| // If a name is empty or too long, it's not a special index |
| // Max length of canonical double: -X.XXXXXXXXXXXXXXXXX-eXXX |
| const int kBufferSize = 24; |
| TNode<Smi> string_length = LoadStringLengthAsSmi(name_string); |
| GotoIf(SmiEqual(string_length, SmiConstant(0)), if_not_special_index); |
| GotoIf(SmiGreaterThan(string_length, SmiConstant(kBufferSize)), |
| if_not_special_index); |
| |
| // If the first character of name is not a digit or '-', or we can't match it |
| // to Infinity or NaN, then this is not a special index. |
| TNode<Int32T> first_char = StringCharCodeAt(name_string, IntPtrConstant(0)); |
| // If the name starts with '-', it can be a negative index. |
| GotoIf(Word32Equal(first_char, Int32Constant('-')), if_maybe_special_index); |
| // If the name starts with 'I', it can be "Infinity". |
| GotoIf(Word32Equal(first_char, Int32Constant('I')), if_maybe_special_index); |
| // If the name starts with 'N', it can be "NaN". |
| GotoIf(Word32Equal(first_char, Int32Constant('N')), if_maybe_special_index); |
| // Finally, if the first character is not a digit either, then we are sure |
| // that the name is not a special index. |
| GotoIf(Uint32LessThan(first_char, Int32Constant('0')), if_not_special_index); |
| GotoIf(Uint32LessThan(Int32Constant('9'), first_char), if_not_special_index); |
| Goto(if_maybe_special_index); |
| } |
| |
| void CodeStubAssembler::TryPrototypeChainLookup( |
| Node* receiver, Node* key, const LookupInHolder& lookup_property_in_holder, |
| const LookupInHolder& lookup_element_in_holder, Label* if_end, |
| Label* if_bailout, Label* if_proxy) { |
| // Ensure receiver is JSReceiver, otherwise bailout. |
| Label if_objectisnotsmi(this); |
| Branch(TaggedIsSmi(receiver), if_bailout, &if_objectisnotsmi); |
| BIND(&if_objectisnotsmi); |
| |
| Node* map = LoadMap(receiver); |
| Node* instance_type = LoadMapInstanceType(map); |
| { |
| Label if_objectisreceiver(this); |
| STATIC_ASSERT(LAST_JS_RECEIVER_TYPE == LAST_TYPE); |
| STATIC_ASSERT(FIRST_JS_RECEIVER_TYPE == JS_PROXY_TYPE); |
| Branch(IsJSReceiverInstanceType(instance_type), &if_objectisreceiver, |
| if_bailout); |
| BIND(&if_objectisreceiver); |
| |
| if (if_proxy) { |
| GotoIf(InstanceTypeEqual(instance_type, JS_PROXY_TYPE), if_proxy); |
| } |
| } |
| |
| VARIABLE(var_index, MachineType::PointerRepresentation()); |
| VARIABLE(var_unique, MachineRepresentation::kTagged); |
| |
| Label if_keyisindex(this), if_iskeyunique(this); |
| TryToName(key, &if_keyisindex, &var_index, &if_iskeyunique, &var_unique, |
| if_bailout); |
| |
| BIND(&if_iskeyunique); |
| { |
| VARIABLE(var_holder, MachineRepresentation::kTagged, receiver); |
| VARIABLE(var_holder_map, MachineRepresentation::kTagged, map); |
| VARIABLE(var_holder_instance_type, MachineRepresentation::kWord32, |
| instance_type); |
| |
| Variable* merged_variables[] = {&var_holder, &var_holder_map, |
| &var_holder_instance_type}; |
| Label loop(this, arraysize(merged_variables), merged_variables); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| Node* holder_map = var_holder_map.value(); |
| Node* holder_instance_type = var_holder_instance_type.value(); |
| |
| Label next_proto(this), check_integer_indexed_exotic(this); |
| lookup_property_in_holder(receiver, var_holder.value(), holder_map, |
| holder_instance_type, var_unique.value(), |
| &check_integer_indexed_exotic, if_bailout); |
| |
| BIND(&check_integer_indexed_exotic); |
| { |
| // Bailout if it can be an integer indexed exotic case. |
| GotoIfNot(InstanceTypeEqual(holder_instance_type, JS_TYPED_ARRAY_TYPE), |
| &next_proto); |
| GotoIfNot(IsString(var_unique.value()), &next_proto); |
| BranchIfMaybeSpecialIndex(CAST(var_unique.value()), if_bailout, |
| &next_proto); |
| } |
| |
| BIND(&next_proto); |
| |
| Node* proto = LoadMapPrototype(holder_map); |
| |
| GotoIf(IsNull(proto), if_end); |
| |
| Node* map = LoadMap(proto); |
| Node* instance_type = LoadMapInstanceType(map); |
| |
| var_holder.Bind(proto); |
| var_holder_map.Bind(map); |
| var_holder_instance_type.Bind(instance_type); |
| Goto(&loop); |
| } |
| } |
| BIND(&if_keyisindex); |
| { |
| VARIABLE(var_holder, MachineRepresentation::kTagged, receiver); |
| VARIABLE(var_holder_map, MachineRepresentation::kTagged, map); |
| VARIABLE(var_holder_instance_type, MachineRepresentation::kWord32, |
| instance_type); |
| |
| Variable* merged_variables[] = {&var_holder, &var_holder_map, |
| &var_holder_instance_type}; |
| Label loop(this, arraysize(merged_variables), merged_variables); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| Label next_proto(this); |
| lookup_element_in_holder(receiver, var_holder.value(), |
| var_holder_map.value(), |
| var_holder_instance_type.value(), |
| var_index.value(), &next_proto, if_bailout); |
| BIND(&next_proto); |
| |
| Node* proto = LoadMapPrototype(var_holder_map.value()); |
| |
| GotoIf(IsNull(proto), if_end); |
| |
| Node* map = LoadMap(proto); |
| Node* instance_type = LoadMapInstanceType(map); |
| |
| var_holder.Bind(proto); |
| var_holder_map.Bind(map); |
| var_holder_instance_type.Bind(instance_type); |
| Goto(&loop); |
| } |
| } |
| } |
| |
| Node* CodeStubAssembler::HasInPrototypeChain(Node* context, Node* object, |
| Node* prototype) { |
| CSA_ASSERT(this, TaggedIsNotSmi(object)); |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| Label return_false(this), return_true(this), |
| return_runtime(this, Label::kDeferred), return_result(this); |
| |
| // Loop through the prototype chain looking for the {prototype}. |
| VARIABLE(var_object_map, MachineRepresentation::kTagged, LoadMap(object)); |
| Label loop(this, &var_object_map); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| // Check if we can determine the prototype directly from the {object_map}. |
| Label if_objectisdirect(this), if_objectisspecial(this, Label::kDeferred); |
| Node* object_map = var_object_map.value(); |
| TNode<Int32T> object_instance_type = LoadMapInstanceType(object_map); |
| Branch(IsSpecialReceiverInstanceType(object_instance_type), |
| &if_objectisspecial, &if_objectisdirect); |
| BIND(&if_objectisspecial); |
| { |
| // The {object_map} is a special receiver map or a primitive map, check |
| // if we need to use the if_objectisspecial path in the runtime. |
| GotoIf(InstanceTypeEqual(object_instance_type, JS_PROXY_TYPE), |
| &return_runtime); |
| Node* object_bitfield = LoadMapBitField(object_map); |
| int mask = Map::HasNamedInterceptorBit::kMask | |
| Map::IsAccessCheckNeededBit::kMask; |
| Branch(IsSetWord32(object_bitfield, mask), &return_runtime, |
| &if_objectisdirect); |
| } |
| BIND(&if_objectisdirect); |
| |
| // Check the current {object} prototype. |
| Node* object_prototype = LoadMapPrototype(object_map); |
| GotoIf(IsNull(object_prototype), &return_false); |
| GotoIf(WordEqual(object_prototype, prototype), &return_true); |
| |
| // Continue with the prototype. |
| CSA_ASSERT(this, TaggedIsNotSmi(object_prototype)); |
| var_object_map.Bind(LoadMap(object_prototype)); |
| Goto(&loop); |
| } |
| |
| BIND(&return_true); |
| var_result.Bind(TrueConstant()); |
| Goto(&return_result); |
| |
| BIND(&return_false); |
| var_result.Bind(FalseConstant()); |
| Goto(&return_result); |
| |
| BIND(&return_runtime); |
| { |
| // Fallback to the runtime implementation. |
| var_result.Bind( |
| CallRuntime(Runtime::kHasInPrototypeChain, context, object, prototype)); |
| } |
| Goto(&return_result); |
| |
| BIND(&return_result); |
| return var_result.value(); |
| } |
| |
| Node* CodeStubAssembler::OrdinaryHasInstance(Node* context, Node* callable, |
| Node* object) { |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| Label return_runtime(this, Label::kDeferred), return_result(this); |
| |
| // Goto runtime if {object} is a Smi. |
| GotoIf(TaggedIsSmi(object), &return_runtime); |
| |
| // Goto runtime if {callable} is a Smi. |
| GotoIf(TaggedIsSmi(callable), &return_runtime); |
| |
| // Load map of {callable}. |
| Node* callable_map = LoadMap(callable); |
| |
| // Goto runtime if {callable} is not a JSFunction. |
| Node* callable_instance_type = LoadMapInstanceType(callable_map); |
| GotoIfNot(InstanceTypeEqual(callable_instance_type, JS_FUNCTION_TYPE), |
| &return_runtime); |
| |
| GotoIfPrototypeRequiresRuntimeLookup(CAST(callable), CAST(callable_map), |
| &return_runtime); |
| |
| // Get the "prototype" (or initial map) of the {callable}. |
| Node* callable_prototype = |
| LoadObjectField(callable, JSFunction::kPrototypeOrInitialMapOffset); |
| { |
| Label callable_prototype_valid(this); |
| VARIABLE(var_callable_prototype, MachineRepresentation::kTagged, |
| callable_prototype); |
| |
| // Resolve the "prototype" if the {callable} has an initial map. Afterwards |
| // the {callable_prototype} will be either the JSReceiver prototype object |
| // or the hole value, which means that no instances of the {callable} were |
| // created so far and hence we should return false. |
| Node* callable_prototype_instance_type = |
| LoadInstanceType(callable_prototype); |
| GotoIfNot(InstanceTypeEqual(callable_prototype_instance_type, MAP_TYPE), |
| &callable_prototype_valid); |
| var_callable_prototype.Bind( |
| LoadObjectField(callable_prototype, Map::kPrototypeOffset)); |
| Goto(&callable_prototype_valid); |
| BIND(&callable_prototype_valid); |
| callable_prototype = var_callable_prototype.value(); |
| } |
| |
| // Loop through the prototype chain looking for the {callable} prototype. |
| var_result.Bind(HasInPrototypeChain(context, object, callable_prototype)); |
| Goto(&return_result); |
| |
| BIND(&return_runtime); |
| { |
| // Fallback to the runtime implementation. |
| var_result.Bind( |
| CallRuntime(Runtime::kOrdinaryHasInstance, context, callable, object)); |
| } |
| Goto(&return_result); |
| |
| BIND(&return_result); |
| return var_result.value(); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::ElementOffsetFromIndex(Node* index_node, |
| ElementsKind kind, |
| ParameterMode mode, |
| int base_size) { |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(index_node, mode)); |
| int element_size_shift = ElementsKindToShiftSize(kind); |
| int element_size = 1 << element_size_shift; |
| int const kSmiShiftBits = kSmiShiftSize + kSmiTagSize; |
| intptr_t index = 0; |
| bool constant_index = false; |
| if (mode == SMI_PARAMETERS) { |
| element_size_shift -= kSmiShiftBits; |
| Smi smi_index; |
| constant_index = ToSmiConstant(index_node, &smi_index); |
| if (constant_index) index = smi_index->value(); |
| index_node = BitcastTaggedToWord(index_node); |
| } else { |
| DCHECK(mode == INTPTR_PARAMETERS); |
| constant_index = ToIntPtrConstant(index_node, index); |
| } |
| if (constant_index) { |
| return IntPtrConstant(base_size + element_size * index); |
| } |
| |
| TNode<WordT> shifted_index = |
| (element_size_shift == 0) |
| ? UncheckedCast<WordT>(index_node) |
| : ((element_size_shift > 0) |
| ? WordShl(index_node, IntPtrConstant(element_size_shift)) |
| : WordSar(index_node, IntPtrConstant(-element_size_shift))); |
| return IntPtrAdd(IntPtrConstant(base_size), Signed(shifted_index)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsOffsetInBounds(SloppyTNode<IntPtrT> offset, |
| SloppyTNode<IntPtrT> length, |
| int header_size, |
| ElementsKind kind) { |
| // Make sure we point to the last field. |
| int element_size = 1 << ElementsKindToShiftSize(kind); |
| int correction = header_size - kHeapObjectTag - element_size; |
| TNode<IntPtrT> last_offset = |
| ElementOffsetFromIndex(length, kind, INTPTR_PARAMETERS, correction); |
| return IntPtrLessThanOrEqual(offset, last_offset); |
| } |
| |
| TNode<FeedbackVector> CodeStubAssembler::LoadFeedbackVector( |
| SloppyTNode<JSFunction> closure, Label* if_undefined) { |
| TNode<Object> maybe_vector = LoadFeedbackVectorUnchecked(closure); |
| if (if_undefined) { |
| GotoIf(IsUndefined(maybe_vector), if_undefined); |
| } |
| return CAST(maybe_vector); |
| } |
| |
| TNode<Object> CodeStubAssembler::LoadFeedbackVectorUnchecked( |
| SloppyTNode<JSFunction> closure) { |
| TNode<FeedbackCell> feedback_cell = |
| CAST(LoadObjectField(closure, JSFunction::kFeedbackCellOffset)); |
| TNode<Object> maybe_vector = |
| LoadObjectField(feedback_cell, FeedbackCell::kValueOffset); |
| return maybe_vector; |
| } |
| |
| TNode<FeedbackVector> CodeStubAssembler::LoadFeedbackVectorForStub() { |
| TNode<JSFunction> function = |
| CAST(LoadFromParentFrame(JavaScriptFrameConstants::kFunctionOffset)); |
| return LoadFeedbackVector(function); |
| } |
| |
| void CodeStubAssembler::UpdateFeedback(Node* feedback, Node* maybe_vector, |
| Node* slot_id) { |
| Label end(this); |
| // If feedback_vector is not valid, then nothing to do. |
| GotoIf(IsUndefined(maybe_vector), &end); |
| |
| // This method is used for binary op and compare feedback. These |
| // vector nodes are initialized with a smi 0, so we can simply OR |
| // our new feedback in place. |
| TNode<FeedbackVector> feedback_vector = CAST(maybe_vector); |
| TNode<MaybeObject> feedback_element = |
| LoadFeedbackVectorSlot(feedback_vector, slot_id); |
| TNode<Smi> previous_feedback = CAST(feedback_element); |
| TNode<Smi> combined_feedback = SmiOr(previous_feedback, CAST(feedback)); |
| |
| GotoIf(SmiEqual(previous_feedback, combined_feedback), &end); |
| { |
| StoreFeedbackVectorSlot(feedback_vector, slot_id, combined_feedback, |
| SKIP_WRITE_BARRIER); |
| ReportFeedbackUpdate(feedback_vector, slot_id, "UpdateFeedback"); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| } |
| |
| void CodeStubAssembler::ReportFeedbackUpdate( |
| SloppyTNode<FeedbackVector> feedback_vector, SloppyTNode<IntPtrT> slot_id, |
| const char* reason) { |
| // Reset profiler ticks. |
| StoreObjectFieldNoWriteBarrier( |
| feedback_vector, FeedbackVector::kProfilerTicksOffset, Int32Constant(0), |
| MachineRepresentation::kWord32); |
| |
| #ifdef V8_TRACE_FEEDBACK_UPDATES |
| // Trace the update. |
| CallRuntime(Runtime::kInterpreterTraceUpdateFeedback, NoContextConstant(), |
| LoadFromParentFrame(JavaScriptFrameConstants::kFunctionOffset), |
| SmiTag(slot_id), StringConstant(reason)); |
| #endif // V8_TRACE_FEEDBACK_UPDATES |
| } |
| |
| void CodeStubAssembler::OverwriteFeedback(Variable* existing_feedback, |
| int new_feedback) { |
| if (existing_feedback == nullptr) return; |
| existing_feedback->Bind(SmiConstant(new_feedback)); |
| } |
| |
| void CodeStubAssembler::CombineFeedback(Variable* existing_feedback, |
| int feedback) { |
| if (existing_feedback == nullptr) return; |
| existing_feedback->Bind( |
| SmiOr(CAST(existing_feedback->value()), SmiConstant(feedback))); |
| } |
| |
| void CodeStubAssembler::CombineFeedback(Variable* existing_feedback, |
| Node* feedback) { |
| if (existing_feedback == nullptr) return; |
| existing_feedback->Bind( |
| SmiOr(CAST(existing_feedback->value()), CAST(feedback))); |
| } |
| |
| void CodeStubAssembler::CheckForAssociatedProtector(Node* name, |
| Label* if_protector) { |
| // This list must be kept in sync with LookupIterator::UpdateProtector! |
| // TODO(jkummerow): Would it be faster to have a bit in Symbol::flags()? |
| GotoIf(WordEqual(name, LoadRoot(RootIndex::kconstructor_string)), |
| if_protector); |
| GotoIf(WordEqual(name, LoadRoot(RootIndex::kiterator_symbol)), if_protector); |
| GotoIf(WordEqual(name, LoadRoot(RootIndex::knext_string)), if_protector); |
| GotoIf(WordEqual(name, LoadRoot(RootIndex::kspecies_symbol)), if_protector); |
| GotoIf(WordEqual(name, LoadRoot(RootIndex::kis_concat_spreadable_symbol)), |
| if_protector); |
| GotoIf(WordEqual(name, LoadRoot(RootIndex::kresolve_string)), if_protector); |
| GotoIf(WordEqual(name, LoadRoot(RootIndex::kthen_string)), if_protector); |
| // Fall through if no case matched. |
| } |
| |
| TNode<Map> CodeStubAssembler::LoadReceiverMap(SloppyTNode<Object> receiver) { |
| return Select<Map>( |
| TaggedIsSmi(receiver), |
| [=] { return CAST(LoadRoot(RootIndex::kHeapNumberMap)); }, |
| [=] { return LoadMap(UncheckedCast<HeapObject>(receiver)); }); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::TryToIntptr(Node* key, Label* miss) { |
| TVARIABLE(IntPtrT, var_intptr_key); |
| Label done(this, &var_intptr_key), key_is_smi(this); |
| GotoIf(TaggedIsSmi(key), &key_is_smi); |
| // Try to convert a heap number to a Smi. |
| GotoIfNot(IsHeapNumber(key), miss); |
| { |
| TNode<Float64T> value = LoadHeapNumberValue(key); |
| TNode<Int32T> int_value = RoundFloat64ToInt32(value); |
| GotoIfNot(Float64Equal(value, ChangeInt32ToFloat64(int_value)), miss); |
| var_intptr_key = ChangeInt32ToIntPtr(int_value); |
| Goto(&done); |
| } |
| |
| BIND(&key_is_smi); |
| { |
| var_intptr_key = SmiUntag(key); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return var_intptr_key.value(); |
| } |
| |
| Node* CodeStubAssembler::EmitKeyedSloppyArguments( |
| Node* receiver, Node* key, Node* value, Label* bailout, |
| ArgumentsAccessMode access_mode) { |
| // Mapped arguments are actual arguments. Unmapped arguments are values added |
| // to the arguments object after it was created for the call. Mapped arguments |
| // are stored in the context at indexes given by elements[key + 2]. Unmapped |
| // arguments are stored as regular indexed properties in the arguments array, |
| // held at elements[1]. See NewSloppyArguments() in runtime.cc for a detailed |
| // look at argument object construction. |
| // |
| // The sloppy arguments elements array has a special format: |
| // |
| // 0: context |
| // 1: unmapped arguments array |
| // 2: mapped_index0, |
| // 3: mapped_index1, |
| // ... |
| // |
| // length is 2 + min(number_of_actual_arguments, number_of_formal_arguments). |
| // If key + 2 >= elements.length then attempt to look in the unmapped |
| // arguments array (given by elements[1]) and return the value at key, missing |
| // to the runtime if the unmapped arguments array is not a fixed array or if |
| // key >= unmapped_arguments_array.length. |
| // |
| // Otherwise, t = elements[key + 2]. If t is the hole, then look up the value |
| // in the unmapped arguments array, as described above. Otherwise, t is a Smi |
| // index into the context array given at elements[0]. Return the value at |
| // context[t]. |
| |
| GotoIfNot(TaggedIsSmi(key), bailout); |
| key = SmiUntag(key); |
| GotoIf(IntPtrLessThan(key, IntPtrConstant(0)), bailout); |
| |
| TNode<FixedArray> elements = CAST(LoadElements(receiver)); |
| TNode<IntPtrT> elements_length = LoadAndUntagFixedArrayBaseLength(elements); |
| |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| if (access_mode == ArgumentsAccessMode::kStore) { |
| var_result.Bind(value); |
| } else { |
| DCHECK(access_mode == ArgumentsAccessMode::kLoad || |
| access_mode == ArgumentsAccessMode::kHas); |
| } |
| Label if_mapped(this), if_unmapped(this), end(this, &var_result); |
| Node* intptr_two = IntPtrConstant(2); |
| Node* adjusted_length = IntPtrSub(elements_length, intptr_two); |
| |
| GotoIf(UintPtrGreaterThanOrEqual(key, adjusted_length), &if_unmapped); |
| |
| TNode<Object> mapped_index = |
| LoadFixedArrayElement(elements, IntPtrAdd(key, intptr_two)); |
| Branch(WordEqual(mapped_index, TheHoleConstant()), &if_unmapped, &if_mapped); |
| |
| BIND(&if_mapped); |
| { |
| TNode<IntPtrT> mapped_index_intptr = SmiUntag(CAST(mapped_index)); |
| TNode<Context> the_context = CAST(LoadFixedArrayElement(elements, 0)); |
| if (access_mode == ArgumentsAccessMode::kLoad) { |
| Node* result = LoadContextElement(the_context, mapped_index_intptr); |
| CSA_ASSERT(this, WordNotEqual(result, TheHoleConstant())); |
| var_result.Bind(result); |
| } else if (access_mode == ArgumentsAccessMode::kHas) { |
| CSA_ASSERT(this, Word32BinaryNot(IsTheHole(LoadContextElement( |
| the_context, mapped_index_intptr)))); |
| var_result.Bind(TrueConstant()); |
| } else { |
| StoreContextElement(the_context, mapped_index_intptr, value); |
| } |
| Goto(&end); |
| } |
| |
| BIND(&if_unmapped); |
| { |
| TNode<HeapObject> backing_store_ho = |
| CAST(LoadFixedArrayElement(elements, 1)); |
| GotoIf(WordNotEqual(LoadMap(backing_store_ho), FixedArrayMapConstant()), |
| bailout); |
| TNode<FixedArray> backing_store = CAST(backing_store_ho); |
| |
| TNode<IntPtrT> backing_store_length = |
| LoadAndUntagFixedArrayBaseLength(backing_store); |
| if (access_mode == ArgumentsAccessMode::kHas) { |
| Label out_of_bounds(this); |
| GotoIf(UintPtrGreaterThanOrEqual(key, backing_store_length), |
| &out_of_bounds); |
| Node* result = LoadFixedArrayElement(backing_store, key); |
| var_result.Bind( |
| SelectBooleanConstant(WordNotEqual(result, TheHoleConstant()))); |
| Goto(&end); |
| |
| BIND(&out_of_bounds); |
| var_result.Bind(FalseConstant()); |
| Goto(&end); |
| } else { |
| GotoIf(UintPtrGreaterThanOrEqual(key, backing_store_length), bailout); |
| |
| // The key falls into unmapped range. |
| if (access_mode == ArgumentsAccessMode::kLoad) { |
| Node* result = LoadFixedArrayElement(backing_store, key); |
| GotoIf(WordEqual(result, TheHoleConstant()), bailout); |
| var_result.Bind(result); |
| } else { |
| StoreFixedArrayElement(backing_store, key, value); |
| } |
| Goto(&end); |
| } |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| TNode<Context> CodeStubAssembler::LoadScriptContext( |
| TNode<Context> context, TNode<IntPtrT> context_index) { |
| TNode<Context> native_context = LoadNativeContext(context); |
| TNode<ScriptContextTable> script_context_table = CAST( |
| LoadContextElement(native_context, Context::SCRIPT_CONTEXT_TABLE_INDEX)); |
| |
| TNode<Context> script_context = CAST(LoadFixedArrayElement( |
| script_context_table, context_index, |
| ScriptContextTable::kFirstContextSlotIndex * kTaggedSize)); |
| return script_context; |
| } |
| |
| namespace { |
| |
| // Converts typed array elements kind to a machine representations. |
| MachineRepresentation ElementsKindToMachineRepresentation(ElementsKind kind) { |
| switch (kind) { |
| case UINT8_CLAMPED_ELEMENTS: |
| case UINT8_ELEMENTS: |
| case INT8_ELEMENTS: |
| return MachineRepresentation::kWord8; |
| case UINT16_ELEMENTS: |
| case INT16_ELEMENTS: |
| return MachineRepresentation::kWord16; |
| case UINT32_ELEMENTS: |
| case INT32_ELEMENTS: |
| return MachineRepresentation::kWord32; |
| case FLOAT32_ELEMENTS: |
| return MachineRepresentation::kFloat32; |
| case FLOAT64_ELEMENTS: |
| return MachineRepresentation::kFloat64; |
| default: |
| UNREACHABLE(); |
| } |
| } |
| |
| } // namespace |
| |
| void CodeStubAssembler::StoreElement(Node* elements, ElementsKind kind, |
| Node* index, Node* value, |
| ParameterMode mode) { |
| if (IsFixedTypedArrayElementsKind(kind)) { |
| if (kind == UINT8_CLAMPED_ELEMENTS) { |
| CSA_ASSERT(this, |
| Word32Equal(value, Word32And(Int32Constant(0xFF), value))); |
| } |
| Node* offset = ElementOffsetFromIndex(index, kind, mode, 0); |
| // TODO(cbruni): Add OOB check once typed. |
| MachineRepresentation rep = ElementsKindToMachineRepresentation(kind); |
| StoreNoWriteBarrier(rep, elements, offset, value); |
| return; |
| } else if (IsDoubleElementsKind(kind)) { |
| // Make sure we do not store signalling NaNs into double arrays. |
| TNode<Float64T> value_silenced = Float64SilenceNaN(value); |
| StoreFixedDoubleArrayElement(CAST(elements), index, value_silenced, mode); |
| } else { |
| WriteBarrierMode barrier_mode = |
| IsSmiElementsKind(kind) ? SKIP_WRITE_BARRIER : UPDATE_WRITE_BARRIER; |
| StoreFixedArrayElement(CAST(elements), index, value, barrier_mode, 0, mode); |
| } |
| } |
| |
| Node* CodeStubAssembler::Int32ToUint8Clamped(Node* int32_value) { |
| Label done(this); |
| Node* int32_zero = Int32Constant(0); |
| Node* int32_255 = Int32Constant(255); |
| VARIABLE(var_value, MachineRepresentation::kWord32, int32_value); |
| GotoIf(Uint32LessThanOrEqual(int32_value, int32_255), &done); |
| var_value.Bind(int32_zero); |
| GotoIf(Int32LessThan(int32_value, int32_zero), &done); |
| var_value.Bind(int32_255); |
| Goto(&done); |
| BIND(&done); |
| return var_value.value(); |
| } |
| |
| Node* CodeStubAssembler::Float64ToUint8Clamped(Node* float64_value) { |
| Label done(this); |
| VARIABLE(var_value, MachineRepresentation::kWord32, Int32Constant(0)); |
| GotoIf(Float64LessThanOrEqual(float64_value, Float64Constant(0.0)), &done); |
| var_value.Bind(Int32Constant(255)); |
| GotoIf(Float64LessThanOrEqual(Float64Constant(255.0), float64_value), &done); |
| { |
| Node* rounded_value = Float64RoundToEven(float64_value); |
| var_value.Bind(TruncateFloat64ToWord32(rounded_value)); |
| Goto(&done); |
| } |
| BIND(&done); |
| return var_value.value(); |
| } |
| |
| Node* CodeStubAssembler::PrepareValueForWriteToTypedArray( |
| TNode<Object> input, ElementsKind elements_kind, TNode<Context> context) { |
| DCHECK(IsFixedTypedArrayElementsKind(elements_kind)); |
| |
| MachineRepresentation rep; |
| switch (elements_kind) { |
| case UINT8_ELEMENTS: |
| case INT8_ELEMENTS: |
| case UINT16_ELEMENTS: |
| case INT16_ELEMENTS: |
| case UINT32_ELEMENTS: |
| case INT32_ELEMENTS: |
| case UINT8_CLAMPED_ELEMENTS: |
| rep = MachineRepresentation::kWord32; |
| break; |
| case FLOAT32_ELEMENTS: |
| rep = MachineRepresentation::kFloat32; |
| break; |
| case FLOAT64_ELEMENTS: |
| rep = MachineRepresentation::kFloat64; |
| break; |
| case BIGINT64_ELEMENTS: |
| case BIGUINT64_ELEMENTS: |
| return ToBigInt(context, input); |
| default: |
| UNREACHABLE(); |
| } |
| |
| VARIABLE(var_result, rep); |
| VARIABLE(var_input, MachineRepresentation::kTagged, input); |
| Label done(this, &var_result), if_smi(this), if_heapnumber_or_oddball(this), |
| convert(this), loop(this, &var_input); |
| Goto(&loop); |
| BIND(&loop); |
| GotoIf(TaggedIsSmi(var_input.value()), &if_smi); |
| // We can handle both HeapNumber and Oddball here, since Oddball has the |
| // same layout as the HeapNumber for the HeapNumber::value field. This |
| // way we can also properly optimize stores of oddballs to typed arrays. |
| GotoIf(IsHeapNumber(var_input.value()), &if_heapnumber_or_oddball); |
| STATIC_ASSERT(HeapNumber::kValueOffset == Oddball::kToNumberRawOffset); |
| Branch(HasInstanceType(var_input.value(), ODDBALL_TYPE), |
| &if_heapnumber_or_oddball, &convert); |
| |
| BIND(&if_heapnumber_or_oddball); |
| { |
| Node* value = UncheckedCast<Float64T>(LoadObjectField( |
| var_input.value(), HeapNumber::kValueOffset, MachineType::Float64())); |
| if (rep == MachineRepresentation::kWord32) { |
| if (elements_kind == UINT8_CLAMPED_ELEMENTS) { |
| value = Float64ToUint8Clamped(value); |
| } else { |
| value = TruncateFloat64ToWord32(value); |
| } |
| } else if (rep == MachineRepresentation::kFloat32) { |
| value = TruncateFloat64ToFloat32(value); |
| } else { |
| DCHECK_EQ(MachineRepresentation::kFloat64, rep); |
| } |
| var_result.Bind(value); |
| Goto(&done); |
| } |
| |
| BIND(&if_smi); |
| { |
| Node* value = SmiToInt32(var_input.value()); |
| if (rep == MachineRepresentation::kFloat32) { |
| value = RoundInt32ToFloat32(value); |
| } else if (rep == MachineRepresentation::kFloat64) { |
| value = ChangeInt32ToFloat64(value); |
| } else { |
| DCHECK_EQ(MachineRepresentation::kWord32, rep); |
| if (elements_kind == UINT8_CLAMPED_ELEMENTS) { |
| value = Int32ToUint8Clamped(value); |
| } |
| } |
| var_result.Bind(value); |
| Goto(&done); |
| } |
| |
| BIND(&convert); |
| { |
| var_input.Bind(CallBuiltin(Builtins::kNonNumberToNumber, context, input)); |
| Goto(&loop); |
| } |
| |
| BIND(&done); |
| return var_result.value(); |
| } |
| |
| void CodeStubAssembler::EmitBigTypedArrayElementStore( |
| TNode<JSTypedArray> object, TNode<FixedTypedArrayBase> elements, |
| TNode<IntPtrT> intptr_key, TNode<Object> value, TNode<Context> context, |
| Label* opt_if_detached) { |
| TNode<BigInt> bigint_value = ToBigInt(context, value); |
| |
| if (opt_if_detached != nullptr) { |
| // Check if buffer has been detached. Must happen after {ToBigInt}! |
| Node* buffer = LoadObjectField(object, JSArrayBufferView::kBufferOffset); |
| GotoIf(IsDetachedBuffer(buffer), opt_if_detached); |
| } |
| |
| TNode<RawPtrT> backing_store = LoadFixedTypedArrayBackingStore(elements); |
| TNode<IntPtrT> offset = ElementOffsetFromIndex(intptr_key, BIGINT64_ELEMENTS, |
| INTPTR_PARAMETERS, 0); |
| EmitBigTypedArrayElementStore(elements, backing_store, offset, bigint_value); |
| } |
| |
| void CodeStubAssembler::BigIntToRawBytes(TNode<BigInt> bigint, |
| TVariable<UintPtrT>* var_low, |
| TVariable<UintPtrT>* var_high) { |
| Label done(this); |
| *var_low = Unsigned(IntPtrConstant(0)); |
| *var_high = Unsigned(IntPtrConstant(0)); |
| TNode<Word32T> bitfield = LoadBigIntBitfield(bigint); |
| TNode<Uint32T> length = DecodeWord32<BigIntBase::LengthBits>(bitfield); |
| TNode<Uint32T> sign = DecodeWord32<BigIntBase::SignBits>(bitfield); |
| GotoIf(Word32Equal(length, Int32Constant(0)), &done); |
| *var_low = LoadBigIntDigit(bigint, 0); |
| if (!Is64()) { |
| Label load_done(this); |
| GotoIf(Word32Equal(length, Int32Constant(1)), &load_done); |
| *var_high = LoadBigIntDigit(bigint, 1); |
| Goto(&load_done); |
| BIND(&load_done); |
| } |
| GotoIf(Word32Equal(sign, Int32Constant(0)), &done); |
| // Negative value. Simulate two's complement. |
| if (!Is64()) { |
| *var_high = Unsigned(IntPtrSub(IntPtrConstant(0), var_high->value())); |
| Label no_carry(this); |
| GotoIf(WordEqual(var_low->value(), IntPtrConstant(0)), &no_carry); |
| *var_high = Unsigned(IntPtrSub(var_high->value(), IntPtrConstant(1))); |
| Goto(&no_carry); |
| BIND(&no_carry); |
| } |
| *var_low = Unsigned(IntPtrSub(IntPtrConstant(0), var_low->value())); |
| Goto(&done); |
| BIND(&done); |
| } |
| |
| void CodeStubAssembler::EmitBigTypedArrayElementStore( |
| TNode<FixedTypedArrayBase> elements, TNode<RawPtrT> backing_store, |
| TNode<IntPtrT> offset, TNode<BigInt> bigint_value) { |
| TVARIABLE(UintPtrT, var_low); |
| // Only used on 32-bit platforms. |
| TVARIABLE(UintPtrT, var_high); |
| BigIntToRawBytes(bigint_value, &var_low, &var_high); |
| |
| // Assert that offset < elements.length. Given that it's an offset for a raw |
| // pointer we correct it by the usual kHeapObjectTag offset. |
| CSA_ASSERT( |
| this, IsOffsetInBounds(offset, LoadAndUntagFixedArrayBaseLength(elements), |
| kHeapObjectTag, BIGINT64_ELEMENTS)); |
| |
| MachineRepresentation rep = WordT::kMachineRepresentation; |
| #if defined(V8_TARGET_BIG_ENDIAN) |
| if (!Is64()) { |
| StoreNoWriteBarrier(rep, backing_store, offset, var_high.value()); |
| StoreNoWriteBarrier(rep, backing_store, |
| IntPtrAdd(offset, IntPtrConstant(kSystemPointerSize)), |
| var_low.value()); |
| } else { |
| StoreNoWriteBarrier(rep, backing_store, offset, var_low.value()); |
| } |
| #else |
| StoreNoWriteBarrier(rep, backing_store, offset, var_low.value()); |
| if (!Is64()) { |
| StoreNoWriteBarrier(rep, backing_store, |
| IntPtrAdd(offset, IntPtrConstant(kSystemPointerSize)), |
| var_high.value()); |
| } |
| #endif |
| } |
| |
| void CodeStubAssembler::EmitElementStore(Node* object, Node* key, Node* value, |
| ElementsKind elements_kind, |
| KeyedAccessStoreMode store_mode, |
| Label* bailout, Node* context) { |
| CSA_ASSERT(this, Word32BinaryNot(IsJSProxy(object))); |
| |
| Node* elements = LoadElements(object); |
| if (!IsSmiOrObjectElementsKind(elements_kind)) { |
| CSA_ASSERT(this, Word32BinaryNot(IsFixedCOWArrayMap(LoadMap(elements)))); |
| } else if (!IsCOWHandlingStoreMode(store_mode)) { |
| GotoIf(IsFixedCOWArrayMap(LoadMap(elements)), bailout); |
| } |
| |
| // TODO(ishell): introduce TryToIntPtrOrSmi() and use OptimalParameterMode(). |
| ParameterMode parameter_mode = INTPTR_PARAMETERS; |
| TNode<IntPtrT> intptr_key = TryToIntptr(key, bailout); |
| |
| if (IsFixedTypedArrayElementsKind(elements_kind)) { |
| Label done(this); |
| |
| // IntegerIndexedElementSet converts value to a Number/BigInt prior to the |
| // bounds check. |
| value = PrepareValueForWriteToTypedArray(CAST(value), elements_kind, |
| CAST(context)); |
| |
| // There must be no allocations between the buffer load and |
| // and the actual store to backing store, because GC may decide that |
| // the buffer is not alive or move the elements. |
| // TODO(ishell): introduce DisallowHeapAllocationCode scope here. |
| |
| // Check if buffer has been detached. |
| Node* buffer = LoadObjectField(object, JSArrayBufferView::kBufferOffset); |
| GotoIf(IsDetachedBuffer(buffer), bailout); |
| |
| // Bounds check. |
| Node* length = |
| TaggedToParameter(LoadJSTypedArrayLength(CAST(object)), parameter_mode); |
| |
| if (store_mode == STORE_NO_TRANSITION_IGNORE_OUT_OF_BOUNDS) { |
| // Skip the store if we write beyond the length or |
| // to a property with a negative integer index. |
| GotoIfNot(UintPtrLessThan(intptr_key, length), &done); |
| } else if (store_mode == STANDARD_STORE) { |
| GotoIfNot(UintPtrLessThan(intptr_key, length), bailout); |
| } else { |
| // This case is produced due to the dispatched call in |
| // ElementsTransitionAndStore and StoreFastElement. |
| // TODO(jgruber): Avoid generating unsupported combinations to save code |
| // size. |
| DebugBreak(); |
| } |
| |
| if (elements_kind == BIGINT64_ELEMENTS || |
| elements_kind == BIGUINT64_ELEMENTS) { |
| TNode<BigInt> bigint_value = UncheckedCast<BigInt>(value); |
| |
| TNode<RawPtrT> backing_store = |
| LoadFixedTypedArrayBackingStore(CAST(elements)); |
| TNode<IntPtrT> offset = ElementOffsetFromIndex( |
| intptr_key, BIGINT64_ELEMENTS, INTPTR_PARAMETERS, 0); |
| EmitBigTypedArrayElementStore(CAST(elements), backing_store, offset, |
| bigint_value); |
| } else { |
| Node* backing_store = LoadFixedTypedArrayBackingStore(CAST(elements)); |
| StoreElement(backing_store, elements_kind, intptr_key, value, |
| parameter_mode); |
| } |
| Goto(&done); |
| |
| BIND(&done); |
| return; |
| } |
| DCHECK(IsFastElementsKind(elements_kind)); |
| |
| Node* length = |
| SelectImpl(IsJSArray(object), [=]() { return LoadJSArrayLength(object); }, |
| [=]() { return LoadFixedArrayBaseLength(elements); }, |
| MachineRepresentation::kTagged); |
| length = TaggedToParameter(length, parameter_mode); |
| |
| // In case value is stored into a fast smi array, assure that the value is |
| // a smi before manipulating the backing store. Otherwise the backing store |
| // may be left in an invalid state. |
| if (IsSmiElementsKind(elements_kind)) { |
| GotoIfNot(TaggedIsSmi(value), bailout); |
| } else if (IsDoubleElementsKind(elements_kind)) { |
| value = TryTaggedToFloat64(value, bailout); |
| } |
| |
| if (IsGrowStoreMode(store_mode)) { |
| elements = CheckForCapacityGrow(object, elements, elements_kind, length, |
| intptr_key, parameter_mode, bailout); |
| } else { |
| GotoIfNot(UintPtrLessThan(intptr_key, length), bailout); |
| } |
| |
| // If we didn't grow {elements}, it might still be COW, in which case we |
| // copy it now. |
| if (!IsSmiOrObjectElementsKind(elements_kind)) { |
| CSA_ASSERT(this, Word32BinaryNot(IsFixedCOWArrayMap(LoadMap(elements)))); |
| } else if (IsCOWHandlingStoreMode(store_mode)) { |
| elements = CopyElementsOnWrite(object, elements, elements_kind, length, |
| parameter_mode, bailout); |
| } |
| |
| CSA_ASSERT(this, Word32BinaryNot(IsFixedCOWArrayMap(LoadMap(elements)))); |
| StoreElement(elements, elements_kind, intptr_key, value, parameter_mode); |
| } |
| |
| Node* CodeStubAssembler::CheckForCapacityGrow(Node* object, Node* elements, |
| ElementsKind kind, Node* length, |
| Node* key, ParameterMode mode, |
| Label* bailout) { |
| DCHECK(IsFastElementsKind(kind)); |
| VARIABLE(checked_elements, MachineRepresentation::kTagged); |
| Label grow_case(this), no_grow_case(this), done(this), |
| grow_bailout(this, Label::kDeferred); |
| |
| Node* condition; |
| if (IsHoleyElementsKind(kind)) { |
| condition = UintPtrGreaterThanOrEqual(key, length); |
| } else { |
| // We don't support growing here unless the value is being appended. |
| condition = WordEqual(key, length); |
| } |
| Branch(condition, &grow_case, &no_grow_case); |
| |
| BIND(&grow_case); |
| { |
| Node* current_capacity = |
| TaggedToParameter(LoadFixedArrayBaseLength(elements), mode); |
| checked_elements.Bind(elements); |
| Label fits_capacity(this); |
| // If key is negative, we will notice in Runtime::kGrowArrayElements. |
| GotoIf(UintPtrLessThan(key, current_capacity), &fits_capacity); |
| |
| { |
| Node* new_elements = TryGrowElementsCapacity( |
| object, elements, kind, key, current_capacity, mode, &grow_bailout); |
| checked_elements.Bind(new_elements); |
| Goto(&fits_capacity); |
| } |
| |
| BIND(&grow_bailout); |
| { |
| Node* tagged_key = mode == SMI_PARAMETERS |
| ? key |
| : ChangeInt32ToTagged(TruncateIntPtrToInt32(key)); |
| Node* maybe_elements = CallRuntime( |
| Runtime::kGrowArrayElements, NoContextConstant(), object, tagged_key); |
| GotoIf(TaggedIsSmi(maybe_elements), bailout); |
| CSA_ASSERT(this, IsFixedArrayWithKind(maybe_elements, kind)); |
| checked_elements.Bind(maybe_elements); |
| Goto(&fits_capacity); |
| } |
| |
| BIND(&fits_capacity); |
| GotoIfNot(IsJSArray(object), &done); |
| |
| Node* new_length = IntPtrAdd(key, IntPtrOrSmiConstant(1, mode)); |
| StoreObjectFieldNoWriteBarrier(object, JSArray::kLengthOffset, |
| ParameterToTagged(new_length, mode)); |
| Goto(&done); |
| } |
| |
| BIND(&no_grow_case); |
| { |
| GotoIfNot(UintPtrLessThan(key, length), bailout); |
| checked_elements.Bind(elements); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return checked_elements.value(); |
| } |
| |
| Node* CodeStubAssembler::CopyElementsOnWrite(Node* object, Node* elements, |
| ElementsKind kind, Node* length, |
| ParameterMode mode, |
| Label* bailout) { |
| VARIABLE(new_elements_var, MachineRepresentation::kTagged, elements); |
| Label done(this); |
| |
| GotoIfNot(IsFixedCOWArrayMap(LoadMap(elements)), &done); |
| { |
| Node* capacity = |
| TaggedToParameter(LoadFixedArrayBaseLength(elements), mode); |
| Node* new_elements = GrowElementsCapacity(object, elements, kind, kind, |
| length, capacity, mode, bailout); |
| new_elements_var.Bind(new_elements); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| return new_elements_var.value(); |
| } |
| |
| void CodeStubAssembler::TransitionElementsKind(Node* object, Node* map, |
| ElementsKind from_kind, |
| ElementsKind to_kind, |
| Label* bailout) { |
| DCHECK(!IsHoleyElementsKind(from_kind) || IsHoleyElementsKind(to_kind)); |
| if (AllocationSite::ShouldTrack(from_kind, to_kind)) { |
| TrapAllocationMemento(object, bailout); |
| } |
| |
| if (!IsSimpleMapChangeTransition(from_kind, to_kind)) { |
| Comment("Non-simple map transition"); |
| Node* elements = LoadElements(object); |
| |
| Label done(this); |
| GotoIf(WordEqual(elements, EmptyFixedArrayConstant()), &done); |
| |
| // TODO(ishell): Use OptimalParameterMode(). |
| ParameterMode mode = INTPTR_PARAMETERS; |
| Node* elements_length = SmiUntag(LoadFixedArrayBaseLength(elements)); |
| Node* array_length = SelectImpl( |
| IsJSArray(object), |
| [=]() { |
| CSA_ASSERT(this, IsFastElementsKind(LoadElementsKind(object))); |
| return SmiUntag(LoadFastJSArrayLength(object)); |
| }, |
| [=]() { return elements_length; }, |
| MachineType::PointerRepresentation()); |
| |
| CSA_ASSERT(this, WordNotEqual(elements_length, IntPtrConstant(0))); |
| |
| GrowElementsCapacity(object, elements, from_kind, to_kind, array_length, |
| elements_length, mode, bailout); |
| Goto(&done); |
| BIND(&done); |
| } |
| |
| StoreMap(object, map); |
| } |
| |
| void CodeStubAssembler::TrapAllocationMemento(Node* object, |
| Label* memento_found) { |
| Comment("[ TrapAllocationMemento"); |
| Label no_memento_found(this); |
| Label top_check(this), map_check(this); |
| |
| TNode<ExternalReference> new_space_top_address = ExternalConstant( |
| ExternalReference::new_space_allocation_top_address(isolate())); |
| const int kMementoMapOffset = JSArray::kSize; |
| const int kMementoLastWordOffset = |
| kMementoMapOffset + AllocationMemento::kSize - kTaggedSize; |
| |
| // Bail out if the object is not in new space. |
| TNode<IntPtrT> object_word = BitcastTaggedToWord(object); |
| TNode<IntPtrT> object_page = PageFromAddress(object_word); |
| { |
| TNode<IntPtrT> page_flags = |
| UncheckedCast<IntPtrT>(Load(MachineType::IntPtr(), object_page, |
| IntPtrConstant(Page::kFlagsOffset))); |
| GotoIf(WordEqual( |
| WordAnd(page_flags, |
| IntPtrConstant(MemoryChunk::kIsInYoungGenerationMask)), |
| IntPtrConstant(0)), |
| &no_memento_found); |
| // TODO(ulan): Support allocation memento for a large object by allocating |
| // additional word for the memento after the large object. |
| GotoIf(WordNotEqual(WordAnd(page_flags, |
| IntPtrConstant(MemoryChunk::kIsLargePageMask)), |
| IntPtrConstant(0)), |
| &no_memento_found); |
| } |
| |
| TNode<IntPtrT> memento_last_word = IntPtrAdd( |
| object_word, IntPtrConstant(kMementoLastWordOffset - kHeapObjectTag)); |
| TNode<IntPtrT> memento_last_word_page = PageFromAddress(memento_last_word); |
| |
| TNode<IntPtrT> new_space_top = UncheckedCast<IntPtrT>( |
| Load(MachineType::Pointer(), new_space_top_address)); |
| TNode<IntPtrT> new_space_top_page = PageFromAddress(new_space_top); |
| |
| // If the object is in new space, we need to check whether respective |
| // potential memento object is on the same page as the current top. |
| GotoIf(WordEqual(memento_last_word_page, new_space_top_page), &top_check); |
| |
| // The object is on a different page than allocation top. Bail out if the |
| // object sits on the page boundary as no memento can follow and we cannot |
| // touch the memory following it. |
| Branch(WordEqual(object_page, memento_last_word_page), &map_check, |
| &no_memento_found); |
| |
| // If top is on the same page as the current object, we need to check whether |
| // we are below top. |
| BIND(&top_check); |
| { |
| Branch(UintPtrGreaterThanOrEqual(memento_last_word, new_space_top), |
| &no_memento_found, &map_check); |
| } |
| |
| // Memento map check. |
| BIND(&map_check); |
| { |
| TNode<Object> memento_map = LoadObjectField(object, kMementoMapOffset); |
| Branch(WordEqual(memento_map, LoadRoot(RootIndex::kAllocationMementoMap)), |
| memento_found, &no_memento_found); |
| } |
| BIND(&no_memento_found); |
| Comment("] TrapAllocationMemento"); |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::PageFromAddress(TNode<IntPtrT> address) { |
| return WordAnd(address, IntPtrConstant(~kPageAlignmentMask)); |
| } |
| |
| TNode<AllocationSite> CodeStubAssembler::CreateAllocationSiteInFeedbackVector( |
| SloppyTNode<FeedbackVector> feedback_vector, TNode<Smi> slot) { |
| TNode<IntPtrT> size = IntPtrConstant(AllocationSite::kSizeWithWeakNext); |
| Node* site = Allocate(size, CodeStubAssembler::kPretenured); |
| StoreMapNoWriteBarrier(site, RootIndex::kAllocationSiteWithWeakNextMap); |
| // Should match AllocationSite::Initialize. |
| TNode<WordT> field = UpdateWord<AllocationSite::ElementsKindBits>( |
| IntPtrConstant(0), IntPtrConstant(GetInitialFastElementsKind())); |
| StoreObjectFieldNoWriteBarrier( |
| site, AllocationSite::kTransitionInfoOrBoilerplateOffset, |
| SmiTag(Signed(field))); |
| |
| // Unlike literals, constructed arrays don't have nested sites |
| TNode<Smi> zero = SmiConstant(0); |
| StoreObjectFieldNoWriteBarrier(site, AllocationSite::kNestedSiteOffset, zero); |
| |
| // Pretenuring calculation field. |
| StoreObjectFieldNoWriteBarrier(site, AllocationSite::kPretenureDataOffset, |
| Int32Constant(0), |
| MachineRepresentation::kWord32); |
| |
| // Pretenuring memento creation count field. |
| StoreObjectFieldNoWriteBarrier( |
| site, AllocationSite::kPretenureCreateCountOffset, Int32Constant(0), |
| MachineRepresentation::kWord32); |
| |
| // Store an empty fixed array for the code dependency. |
| StoreObjectFieldRoot(site, AllocationSite::kDependentCodeOffset, |
| RootIndex::kEmptyWeakFixedArray); |
| |
| // Link the object to the allocation site list |
| TNode<ExternalReference> site_list = ExternalConstant( |
| ExternalReference::allocation_sites_list_address(isolate())); |
| TNode<Object> next_site = CAST(LoadBufferObject(site_list, 0)); |
| |
| // TODO(mvstanton): This is a store to a weak pointer, which we may want to |
| // mark as such in order to skip the write barrier, once we have a unified |
| // system for weakness. For now we decided to keep it like this because having |
| // an initial write barrier backed store makes this pointer strong until the |
| // next GC, and allocation sites are designed to survive several GCs anyway. |
| StoreObjectField(site, AllocationSite::kWeakNextOffset, next_site); |
| StoreFullTaggedNoWriteBarrier(site_list, site); |
| |
| StoreFeedbackVectorSlot(feedback_vector, slot, site, UPDATE_WRITE_BARRIER, 0, |
| SMI_PARAMETERS); |
| return CAST(site); |
| } |
| |
| TNode<MaybeObject> CodeStubAssembler::StoreWeakReferenceInFeedbackVector( |
| SloppyTNode<FeedbackVector> feedback_vector, Node* slot, |
| SloppyTNode<HeapObject> value, int additional_offset, |
| ParameterMode parameter_mode) { |
| TNode<MaybeObject> weak_value = MakeWeak(value); |
| StoreFeedbackVectorSlot(feedback_vector, slot, weak_value, |
| UPDATE_WRITE_BARRIER, additional_offset, |
| parameter_mode); |
| return weak_value; |
| } |
| |
| TNode<BoolT> CodeStubAssembler::NotHasBoilerplate( |
| TNode<Object> maybe_literal_site) { |
| return TaggedIsSmi(maybe_literal_site); |
| } |
| |
| TNode<Smi> CodeStubAssembler::LoadTransitionInfo( |
| TNode<AllocationSite> allocation_site) { |
| TNode<Smi> transition_info = CAST(LoadObjectField( |
| allocation_site, AllocationSite::kTransitionInfoOrBoilerplateOffset)); |
| return transition_info; |
| } |
| |
| TNode<JSObject> CodeStubAssembler::LoadBoilerplate( |
| TNode<AllocationSite> allocation_site) { |
| TNode<JSObject> boilerplate = CAST(LoadObjectField( |
| allocation_site, AllocationSite::kTransitionInfoOrBoilerplateOffset)); |
| return boilerplate; |
| } |
| |
| TNode<Int32T> CodeStubAssembler::LoadElementsKind( |
| TNode<AllocationSite> allocation_site) { |
| TNode<Smi> transition_info = LoadTransitionInfo(allocation_site); |
| TNode<Int32T> elements_kind = |
| Signed(DecodeWord32<AllocationSite::ElementsKindBits>( |
| SmiToInt32(transition_info))); |
| CSA_ASSERT(this, IsFastElementsKind(elements_kind)); |
| return elements_kind; |
| } |
| |
| Node* CodeStubAssembler::BuildFastLoop( |
| const CodeStubAssembler::VariableList& vars, Node* start_index, |
| Node* end_index, const FastLoopBody& body, int increment, |
| ParameterMode parameter_mode, IndexAdvanceMode advance_mode) { |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(start_index, parameter_mode)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(end_index, parameter_mode)); |
| MachineRepresentation index_rep = (parameter_mode == INTPTR_PARAMETERS) |
| ? MachineType::PointerRepresentation() |
| : MachineRepresentation::kTaggedSigned; |
| VARIABLE(var, index_rep, start_index); |
| VariableList vars_copy(vars.begin(), vars.end(), zone()); |
| vars_copy.push_back(&var); |
| Label loop(this, vars_copy); |
| Label after_loop(this); |
| // Introduce an explicit second check of the termination condition before the |
| // loop that helps turbofan generate better code. If there's only a single |
| // check, then the CodeStubAssembler forces it to be at the beginning of the |
| // loop requiring a backwards branch at the end of the loop (it's not possible |
| // to force the loop header check at the end of the loop and branch forward to |
| // it from the pre-header). The extra branch is slower in the case that the |
| // loop actually iterates. |
| Node* first_check = WordEqual(var.value(), end_index); |
| int32_t first_check_val; |
| if (ToInt32Constant(first_check, first_check_val)) { |
| if (first_check_val) return var.value(); |
| Goto(&loop); |
| } else { |
| Branch(first_check, &after_loop, &loop); |
| } |
| |
| BIND(&loop); |
| { |
| if (advance_mode == IndexAdvanceMode::kPre) { |
| Increment(&var, increment, parameter_mode); |
| } |
| body(var.value()); |
| if (advance_mode == IndexAdvanceMode::kPost) { |
| Increment(&var, increment, parameter_mode); |
| } |
| Branch(WordNotEqual(var.value(), end_index), &loop, &after_loop); |
| } |
| BIND(&after_loop); |
| return var.value(); |
| } |
| |
| void CodeStubAssembler::BuildFastFixedArrayForEach( |
| const CodeStubAssembler::VariableList& vars, Node* fixed_array, |
| ElementsKind kind, Node* first_element_inclusive, |
| Node* last_element_exclusive, const FastFixedArrayForEachBody& body, |
| ParameterMode mode, ForEachDirection direction) { |
| STATIC_ASSERT(FixedArray::kHeaderSize == FixedDoubleArray::kHeaderSize); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(first_element_inclusive, mode)); |
| CSA_SLOW_ASSERT(this, MatchesParameterMode(last_element_exclusive, mode)); |
| CSA_SLOW_ASSERT(this, Word32Or(IsFixedArrayWithKind(fixed_array, kind), |
| IsPropertyArray(fixed_array))); |
| int32_t first_val; |
| bool constant_first = ToInt32Constant(first_element_inclusive, first_val); |
| int32_t last_val; |
| bool constent_last = ToInt32Constant(last_element_exclusive, last_val); |
| if (constant_first && constent_last) { |
| int delta = last_val - first_val; |
| DCHECK_GE(delta, 0); |
| if (delta <= kElementLoopUnrollThreshold) { |
| if (direction == ForEachDirection::kForward) { |
| for (int i = first_val; i < last_val; ++i) { |
| Node* index = IntPtrConstant(i); |
| Node* offset = |
| ElementOffsetFromIndex(index, kind, INTPTR_PARAMETERS, |
| FixedArray::kHeaderSize - kHeapObjectTag); |
| body(fixed_array, offset); |
| } |
| } else { |
| for (int i = last_val - 1; i >= first_val; --i) { |
| Node* index = IntPtrConstant(i); |
| Node* offset = |
| ElementOffsetFromIndex(index, kind, INTPTR_PARAMETERS, |
| FixedArray::kHeaderSize - kHeapObjectTag); |
| body(fixed_array, offset); |
| } |
| } |
| return; |
| } |
| } |
| |
| Node* start = |
| ElementOffsetFromIndex(first_element_inclusive, kind, mode, |
| FixedArray::kHeaderSize - kHeapObjectTag); |
| Node* limit = |
| ElementOffsetFromIndex(last_element_exclusive, kind, mode, |
| FixedArray::kHeaderSize - kHeapObjectTag); |
| if (direction == ForEachDirection::kReverse) std::swap(start, limit); |
| |
| int increment = IsDoubleElementsKind(kind) ? kDoubleSize : kTaggedSize; |
| BuildFastLoop( |
| vars, start, limit, |
| [fixed_array, &body](Node* offset) { body(fixed_array, offset); }, |
| direction == ForEachDirection::kReverse ? -increment : increment, |
| INTPTR_PARAMETERS, |
| direction == ForEachDirection::kReverse ? IndexAdvanceMode::kPre |
| : IndexAdvanceMode::kPost); |
| } |
| |
| void CodeStubAssembler::GotoIfFixedArraySizeDoesntFitInNewSpace( |
| Node* element_count, Label* doesnt_fit, int base_size, ParameterMode mode) { |
| GotoIf(FixedArraySizeDoesntFitInNewSpace(element_count, base_size, mode), |
| doesnt_fit); |
| } |
| |
| void CodeStubAssembler::InitializeFieldsWithRoot(Node* object, |
| Node* start_offset, |
| Node* end_offset, |
| RootIndex root_index) { |
| CSA_SLOW_ASSERT(this, TaggedIsNotSmi(object)); |
| start_offset = IntPtrAdd(start_offset, IntPtrConstant(-kHeapObjectTag)); |
| end_offset = IntPtrAdd(end_offset, IntPtrConstant(-kHeapObjectTag)); |
| Node* root_value = LoadRoot(root_index); |
| BuildFastLoop( |
| end_offset, start_offset, |
| [this, object, root_value](Node* current) { |
| StoreNoWriteBarrier(MachineRepresentation::kTagged, object, current, |
| root_value); |
| }, |
| -kTaggedSize, INTPTR_PARAMETERS, |
| CodeStubAssembler::IndexAdvanceMode::kPre); |
| } |
| |
| void CodeStubAssembler::BranchIfNumberRelationalComparison( |
| Operation op, Node* left, Node* right, Label* if_true, Label* if_false) { |
| CSA_SLOW_ASSERT(this, IsNumber(left)); |
| CSA_SLOW_ASSERT(this, IsNumber(right)); |
| |
| Label do_float_comparison(this); |
| TVARIABLE(Float64T, var_left_float); |
| TVARIABLE(Float64T, var_right_float); |
| |
| Branch( |
| TaggedIsSmi(left), |
| [&] { |
| TNode<Smi> smi_left = CAST(left); |
| |
| Branch( |
| TaggedIsSmi(right), |
| [&] { |
| TNode<Smi> smi_right = CAST(right); |
| |
| // Both {left} and {right} are Smi, so just perform a fast |
| // Smi comparison. |
| switch (op) { |
| case Operation::kEqual: |
| BranchIfSmiEqual(smi_left, smi_right, if_true, if_false); |
| break; |
| case Operation::kLessThan: |
| BranchIfSmiLessThan(smi_left, smi_right, if_true, if_false); |
| break; |
| case Operation::kLessThanOrEqual: |
| BranchIfSmiLessThanOrEqual(smi_left, smi_right, if_true, |
| if_false); |
| break; |
| case Operation::kGreaterThan: |
| BranchIfSmiLessThan(smi_right, smi_left, if_true, if_false); |
| break; |
| case Operation::kGreaterThanOrEqual: |
| BranchIfSmiLessThanOrEqual(smi_right, smi_left, if_true, |
| if_false); |
| break; |
| default: |
| UNREACHABLE(); |
| } |
| }, |
| [&] { |
| CSA_ASSERT(this, IsHeapNumber(right)); |
| var_left_float = SmiToFloat64(smi_left); |
| var_right_float = LoadHeapNumberValue(right); |
| Goto(&do_float_comparison); |
| }); |
| }, |
| [&] { |
| CSA_ASSERT(this, IsHeapNumber(left)); |
| var_left_float = LoadHeapNumberValue(left); |
| |
| Branch( |
| TaggedIsSmi(right), |
| [&] { |
| var_right_float = SmiToFloat64(right); |
| Goto(&do_float_comparison); |
| }, |
| [&] { |
| CSA_ASSERT(this, IsHeapNumber(right)); |
| var_right_float = LoadHeapNumberValue(right); |
| Goto(&do_float_comparison); |
| }); |
| }); |
| |
| BIND(&do_float_comparison); |
| { |
| switch (op) { |
| case Operation::kEqual: |
| Branch(Float64Equal(var_left_float.value(), var_right_float.value()), |
| if_true, if_false); |
| break; |
| case Operation::kLessThan: |
| Branch(Float64LessThan(var_left_float.value(), var_right_float.value()), |
| if_true, if_false); |
| break; |
| case Operation::kLessThanOrEqual: |
| Branch(Float64LessThanOrEqual(var_left_float.value(), |
| var_right_float.value()), |
| if_true, if_false); |
| break; |
| case Operation::kGreaterThan: |
| Branch( |
| Float64GreaterThan(var_left_float.value(), var_right_float.value()), |
| if_true, if_false); |
| break; |
| case Operation::kGreaterThanOrEqual: |
| Branch(Float64GreaterThanOrEqual(var_left_float.value(), |
| var_right_float.value()), |
| if_true, if_false); |
| break; |
| default: |
| UNREACHABLE(); |
| } |
| } |
| } |
| |
| void CodeStubAssembler::GotoIfNumberGreaterThanOrEqual(Node* left, Node* right, |
| Label* if_true) { |
| Label if_false(this); |
| BranchIfNumberRelationalComparison(Operation::kGreaterThanOrEqual, left, |
| right, if_true, &if_false); |
| BIND(&if_false); |
| } |
| |
| namespace { |
| Operation Reverse(Operation op) { |
| switch (op) { |
| case Operation::kLessThan: |
| return Operation::kGreaterThan; |
| case Operation::kLessThanOrEqual: |
| return Operation::kGreaterThanOrEqual; |
| case Operation::kGreaterThan: |
| return Operation::kLessThan; |
| case Operation::kGreaterThanOrEqual: |
| return Operation::kLessThanOrEqual; |
| default: |
| break; |
| } |
| UNREACHABLE(); |
| } |
| } // anonymous namespace |
| |
| Node* CodeStubAssembler::RelationalComparison(Operation op, Node* left, |
| Node* right, Node* context, |
| Variable* var_type_feedback) { |
| Label return_true(this), return_false(this), do_float_comparison(this), |
| end(this); |
| TVARIABLE(Oddball, var_result); // Actually only "true" or "false". |
| TVARIABLE(Float64T, var_left_float); |
| TVARIABLE(Float64T, var_right_float); |
| |
| // We might need to loop several times due to ToPrimitive and/or ToNumeric |
| // conversions. |
| VARIABLE(var_left, MachineRepresentation::kTagged, left); |
| VARIABLE(var_right, MachineRepresentation::kTagged, right); |
| VariableList loop_variable_list({&var_left, &var_right}, zone()); |
| if (var_type_feedback != nullptr) { |
| // Initialize the type feedback to None. The current feedback is combined |
| // with the previous feedback. |
| var_type_feedback->Bind(SmiConstant(CompareOperationFeedback::kNone)); |
| loop_variable_list.push_back(var_type_feedback); |
| } |
| Label loop(this, loop_variable_list); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| left = var_left.value(); |
| right = var_right.value(); |
| |
| Label if_left_smi(this), if_left_not_smi(this); |
| Branch(TaggedIsSmi(left), &if_left_smi, &if_left_not_smi); |
| |
| BIND(&if_left_smi); |
| { |
| TNode<Smi> smi_left = CAST(left); |
| Label if_right_smi(this), if_right_heapnumber(this), |
| if_right_bigint(this, Label::kDeferred), |
| if_right_not_numeric(this, Label::kDeferred); |
| GotoIf(TaggedIsSmi(right), &if_right_smi); |
| Node* right_map = LoadMap(right); |
| GotoIf(IsHeapNumberMap(right_map), &if_right_heapnumber); |
| Node* right_instance_type = LoadMapInstanceType(right_map); |
| Branch(IsBigIntInstanceType(right_instance_type), &if_right_bigint, |
| &if_right_not_numeric); |
| |
| BIND(&if_right_smi); |
| { |
| TNode<Smi> smi_right = CAST(right); |
| CombineFeedback(var_type_feedback, |
| CompareOperationFeedback::kSignedSmall); |
| switch (op) { |
| case Operation::kLessThan: |
| BranchIfSmiLessThan(smi_left, smi_right, &return_true, |
| &return_false); |
| break; |
| case Operation::kLessThanOrEqual: |
| BranchIfSmiLessThanOrEqual(smi_left, smi_right, &return_true, |
| &return_false); |
| break; |
| case Operation::kGreaterThan: |
| BranchIfSmiLessThan(smi_right, smi_left, &return_true, |
| &return_false); |
| break; |
| case Operation::kGreaterThanOrEqual: |
| BranchIfSmiLessThanOrEqual(smi_right, smi_left, &return_true, |
| &return_false); |
| break; |
| default: |
| UNREACHABLE(); |
| } |
| } |
| |
| BIND(&if_right_heapnumber); |
| { |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kNumber); |
| var_left_float = SmiToFloat64(smi_left); |
| var_right_float = LoadHeapNumberValue(right); |
| Goto(&do_float_comparison); |
| } |
| |
| BIND(&if_right_bigint); |
| { |
| OverwriteFeedback(var_type_feedback, CompareOperationFeedback::kAny); |
| var_result = CAST(CallRuntime(Runtime::kBigIntCompareToNumber, |
| NoContextConstant(), |
| SmiConstant(Reverse(op)), right, left)); |
| Goto(&end); |
| } |
| |
| BIND(&if_right_not_numeric); |
| { |
| OverwriteFeedback(var_type_feedback, CompareOperationFeedback::kAny); |
| // Convert {right} to a Numeric; we don't need to perform the |
| // dedicated ToPrimitive(right, hint Number) operation, as the |
| // ToNumeric(right) will by itself already invoke ToPrimitive with |
| // a Number hint. |
| var_right.Bind( |
| CallBuiltin(Builtins::kNonNumberToNumeric, context, right)); |
| Goto(&loop); |
| } |
| } |
| |
| BIND(&if_left_not_smi); |
| { |
| Node* left_map = LoadMap(left); |
| |
| Label if_right_smi(this), if_right_not_smi(this); |
| Branch(TaggedIsSmi(right), &if_right_smi, &if_right_not_smi); |
| |
| BIND(&if_right_smi); |
| { |
| Label if_left_heapnumber(this), if_left_bigint(this, Label::kDeferred), |
| if_left_not_numeric(this, Label::kDeferred); |
| GotoIf(IsHeapNumberMap(left_map), &if_left_heapnumber); |
| Node* left_instance_type = LoadMapInstanceType(left_map); |
| Branch(IsBigIntInstanceType(left_instance_type), &if_left_bigint, |
| &if_left_not_numeric); |
| |
| BIND(&if_left_heapnumber); |
| { |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kNumber); |
| var_left_float = LoadHeapNumberValue(left); |
| var_right_float = SmiToFloat64(right); |
| Goto(&do_float_comparison); |
| } |
| |
| BIND(&if_left_bigint); |
| { |
| OverwriteFeedback(var_type_feedback, CompareOperationFeedback::kAny); |
| var_result = CAST(CallRuntime(Runtime::kBigIntCompareToNumber, |
| NoContextConstant(), SmiConstant(op), |
| left, right)); |
| Goto(&end); |
| } |
| |
| BIND(&if_left_not_numeric); |
| { |
| OverwriteFeedback(var_type_feedback, CompareOperationFeedback::kAny); |
| // Convert {left} to a Numeric; we don't need to perform the |
| // dedicated ToPrimitive(left, hint Number) operation, as the |
| // ToNumeric(left) will by itself already invoke ToPrimitive with |
| // a Number hint. |
| var_left.Bind( |
| CallBuiltin(Builtins::kNonNumberToNumeric, context, left)); |
| Goto(&loop); |
| } |
| } |
| |
| BIND(&if_right_not_smi); |
| { |
| Node* right_map = LoadMap(right); |
| |
| Label if_left_heapnumber(this), if_left_bigint(this, Label::kDeferred), |
| if_left_string(this), if_left_other(this, Label::kDeferred); |
| GotoIf(IsHeapNumberMap(left_map), &if_left_heapnumber); |
| Node* left_instance_type = LoadMapInstanceType(left_map); |
| GotoIf(IsBigIntInstanceType(left_instance_type), &if_left_bigint); |
| Branch(IsStringInstanceType(left_instance_type), &if_left_string, |
| &if_left_other); |
| |
| BIND(&if_left_heapnumber); |
| { |
| Label if_right_heapnumber(this), |
| if_right_bigint(this, Label::kDeferred), |
| if_right_not_numeric(this, Label::kDeferred); |
| GotoIf(WordEqual(right_map, left_map), &if_right_heapnumber); |
| Node* right_instance_type = LoadMapInstanceType(right_map); |
| Branch(IsBigIntInstanceType(right_instance_type), &if_right_bigint, |
| &if_right_not_numeric); |
| |
| BIND(&if_right_heapnumber); |
| { |
| CombineFeedback(var_type_feedback, |
| CompareOperationFeedback::kNumber); |
| var_left_float = LoadHeapNumberValue(left); |
| var_right_float = LoadHeapNumberValue(right); |
| Goto(&do_float_comparison); |
| } |
| |
| BIND(&if_right_bigint); |
| { |
| OverwriteFeedback(var_type_feedback, |
| CompareOperationFeedback::kAny); |
| var_result = CAST(CallRuntime( |
| Runtime::kBigIntCompareToNumber, NoContextConstant(), |
| SmiConstant(Reverse(op)), right, left)); |
| Goto(&end); |
| } |
| |
| BIND(&if_right_not_numeric); |
| { |
| OverwriteFeedback(var_type_feedback, |
| CompareOperationFeedback::kAny); |
| // Convert {right} to a Numeric; we don't need to perform |
| // dedicated ToPrimitive(right, hint Number) operation, as the |
| // ToNumeric(right) will by itself already invoke ToPrimitive with |
| // a Number hint. |
| var_right.Bind( |
| CallBuiltin(Builtins::kNonNumberToNumeric, context, right)); |
| Goto(&loop); |
| } |
| } |
| |
| BIND(&if_left_bigint); |
| { |
| Label if_right_heapnumber(this), if_right_bigint(this), |
| if_right_string(this), if_right_other(this); |
| GotoIf(IsHeapNumberMap(right_map), &if_right_heapnumber); |
| Node* right_instance_type = LoadMapInstanceType(right_map); |
| GotoIf(IsBigIntInstanceType(right_instance_type), &if_right_bigint); |
| Branch(IsStringInstanceType(right_instance_type), &if_right_string, |
| &if_right_other); |
| |
| BIND(&if_right_heapnumber); |
| { |
| OverwriteFeedback(var_type_feedback, |
| CompareOperationFeedback::kAny); |
| var_result = CAST(CallRuntime(Runtime::kBigIntCompareToNumber, |
| NoContextConstant(), SmiConstant(op), |
| left, right)); |
| Goto(&end); |
| } |
| |
| BIND(&if_right_bigint); |
| { |
| CombineFeedback(var_type_feedback, |
| CompareOperationFeedback::kBigInt); |
| var_result = CAST(CallRuntime(Runtime::kBigIntCompareToBigInt, |
| NoContextConstant(), SmiConstant(op), |
| left, right)); |
| Goto(&end); |
| } |
| |
| BIND(&if_right_string); |
| { |
| OverwriteFeedback(var_type_feedback, |
| CompareOperationFeedback::kAny); |
| var_result = CAST(CallRuntime(Runtime::kBigIntCompareToString, |
| NoContextConstant(), SmiConstant(op), |
| left, right)); |
| Goto(&end); |
| } |
| |
| // {right} is not a Number, BigInt, or String. |
| BIND(&if_right_other); |
| { |
| OverwriteFeedback(var_type_feedback, |
| CompareOperationFeedback::kAny); |
| // Convert {right} to a Numeric; we don't need to perform |
| // dedicated ToPrimitive(right, hint Number) operation, as the |
| // ToNumeric(right) will by itself already invoke ToPrimitive with |
| // a Number hint. |
| var_right.Bind( |
| CallBuiltin(Builtins::kNonNumberToNumeric, context, right)); |
| Goto(&loop); |
| } |
| } |
| |
| BIND(&if_left_string); |
| { |
| Node* right_instance_type = LoadMapInstanceType(right_map); |
| |
| Label if_right_not_string(this, Label::kDeferred); |
| GotoIfNot(IsStringInstanceType(right_instance_type), |
| &if_right_not_string); |
| |
| // Both {left} and {right} are strings. |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kString); |
| Builtins::Name builtin; |
| switch (op) { |
| case Operation::kLessThan: |
| builtin = Builtins::kStringLessThan; |
| break; |
| case Operation::kLessThanOrEqual: |
| builtin = Builtins::kStringLessThanOrEqual; |
| break; |
| case Operation::kGreaterThan: |
| builtin = Builtins::kStringGreaterThan; |
| break; |
| case Operation::kGreaterThanOrEqual: |
| builtin = Builtins::kStringGreaterThanOrEqual; |
| break; |
| default: |
| UNREACHABLE(); |
| } |
| var_result = CAST(CallBuiltin(builtin, context, left, right)); |
| Goto(&end); |
| |
| BIND(&if_right_not_string); |
| { |
| OverwriteFeedback(var_type_feedback, |
| CompareOperationFeedback::kAny); |
| // {left} is a String, while {right} isn't. Check if {right} is |
| // a BigInt, otherwise call ToPrimitive(right, hint Number) if |
| // {right} is a receiver, or ToNumeric(left) and then |
| // ToNumeric(right) in the other cases. |
| STATIC_ASSERT(LAST_JS_RECEIVER_TYPE == LAST_TYPE); |
| Label if_right_bigint(this), |
| if_right_receiver(this, Label::kDeferred); |
| GotoIf(IsBigIntInstanceType(right_instance_type), &if_right_bigint); |
| GotoIf(IsJSReceiverInstanceType(right_instance_type), |
| &if_right_receiver); |
| |
| var_left.Bind( |
| CallBuiltin(Builtins::kNonNumberToNumeric, context, left)); |
| var_right.Bind(CallBuiltin(Builtins::kToNumeric, context, right)); |
| Goto(&loop); |
| |
| BIND(&if_right_bigint); |
| { |
| var_result = CAST(CallRuntime( |
| Runtime::kBigIntCompareToString, NoContextConstant(), |
| SmiConstant(Reverse(op)), right, left)); |
| Goto(&end); |
| } |
| |
| BIND(&if_right_receiver); |
| { |
| Callable callable = CodeFactory::NonPrimitiveToPrimitive( |
| isolate(), ToPrimitiveHint::kNumber); |
| var_right.Bind(CallStub(callable, context, right)); |
| Goto(&loop); |
| } |
| } |
| } |
| |
| BIND(&if_left_other); |
| { |
| // {left} is neither a Numeric nor a String, and {right} is not a Smi. |
| if (var_type_feedback != nullptr) { |
| // Collect NumberOrOddball feedback if {left} is an Oddball |
| // and {right} is either a HeapNumber or Oddball. Otherwise collect |
| // Any feedback. |
| Label collect_any_feedback(this), collect_oddball_feedback(this), |
| collect_feedback_done(this); |
| GotoIfNot(InstanceTypeEqual(left_instance_type, ODDBALL_TYPE), |
| &collect_any_feedback); |
| |
| GotoIf(IsHeapNumberMap(right_map), &collect_oddball_feedback); |
| Node* right_instance_type = LoadMapInstanceType(right_map); |
| Branch(InstanceTypeEqual(right_instance_type, ODDBALL_TYPE), |
| &collect_oddball_feedback, &collect_any_feedback); |
| |
| BIND(&collect_oddball_feedback); |
| { |
| CombineFeedback(var_type_feedback, |
| CompareOperationFeedback::kNumberOrOddball); |
| Goto(&collect_feedback_done); |
| } |
| |
| BIND(&collect_any_feedback); |
| { |
| OverwriteFeedback(var_type_feedback, |
| CompareOperationFeedback::kAny); |
| Goto(&collect_feedback_done); |
| } |
| |
| BIND(&collect_feedback_done); |
| } |
| |
| // If {left} is a receiver, call ToPrimitive(left, hint Number). |
| // Otherwise call ToNumeric(right) and then ToNumeric(left), the |
| // order here is important as it's observable by user code. |
| STATIC_ASSERT(LAST_JS_RECEIVER_TYPE == LAST_TYPE); |
| Label if_left_receiver(this, Label::kDeferred); |
| GotoIf(IsJSReceiverInstanceType(left_instance_type), |
| &if_left_receiver); |
| |
| var_right.Bind(CallBuiltin(Builtins::kToNumeric, context, right)); |
| var_left.Bind( |
| CallBuiltin(Builtins::kNonNumberToNumeric, context, left)); |
| Goto(&loop); |
| |
| BIND(&if_left_receiver); |
| { |
| Callable callable = CodeFactory::NonPrimitiveToPrimitive( |
| isolate(), ToPrimitiveHint::kNumber); |
| var_left.Bind(CallStub(callable, context, left)); |
| Goto(&loop); |
| } |
| } |
| } |
| } |
| } |
| |
| BIND(&do_float_comparison); |
| { |
| switch (op) { |
| case Operation::kLessThan: |
| Branch(Float64LessThan(var_left_float.value(), var_right_float.value()), |
| &return_true, &return_false); |
| break; |
| case Operation::kLessThanOrEqual: |
| Branch(Float64LessThanOrEqual(var_left_float.value(), |
| var_right_float.value()), |
| &return_true, &return_false); |
| break; |
| case Operation::kGreaterThan: |
| Branch( |
| Float64GreaterThan(var_left_float.value(), var_right_float.value()), |
| &return_true, &return_false); |
| break; |
| case Operation::kGreaterThanOrEqual: |
| Branch(Float64GreaterThanOrEqual(var_left_float.value(), |
| var_right_float.value()), |
| &return_true, &return_false); |
| break; |
| default: |
| UNREACHABLE(); |
| } |
| } |
| |
| BIND(&return_true); |
| { |
| var_result = TrueConstant(); |
| Goto(&end); |
| } |
| |
| BIND(&return_false); |
| { |
| var_result = FalseConstant(); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| TNode<Smi> CodeStubAssembler::CollectFeedbackForString( |
| SloppyTNode<Int32T> instance_type) { |
| TNode<Smi> feedback = SelectSmiConstant( |
| Word32Equal( |
| Word32And(instance_type, Int32Constant(kIsNotInternalizedMask)), |
| Int32Constant(kInternalizedTag)), |
| CompareOperationFeedback::kInternalizedString, |
| CompareOperationFeedback::kString); |
| return feedback; |
| } |
| |
| void CodeStubAssembler::GenerateEqual_Same(Node* value, Label* if_equal, |
| Label* if_notequal, |
| Variable* var_type_feedback) { |
| // In case of abstract or strict equality checks, we need additional checks |
| // for NaN values because they are not considered equal, even if both the |
| // left and the right hand side reference exactly the same value. |
| |
| Label if_smi(this), if_heapnumber(this); |
| GotoIf(TaggedIsSmi(value), &if_smi); |
| |
| Node* value_map = LoadMap(value); |
| GotoIf(IsHeapNumberMap(value_map), &if_heapnumber); |
| |
| // For non-HeapNumbers, all we do is collect type feedback. |
| if (var_type_feedback != nullptr) { |
| Node* instance_type = LoadMapInstanceType(value_map); |
| |
| Label if_string(this), if_receiver(this), if_oddball(this), if_symbol(this), |
| if_bigint(this); |
| GotoIf(IsStringInstanceType(instance_type), &if_string); |
| GotoIf(IsJSReceiverInstanceType(instance_type), &if_receiver); |
| GotoIf(IsOddballInstanceType(instance_type), &if_oddball); |
| Branch(IsBigIntInstanceType(instance_type), &if_bigint, &if_symbol); |
| |
| BIND(&if_string); |
| { |
| CSA_ASSERT(this, IsString(value)); |
| CombineFeedback(var_type_feedback, |
| CollectFeedbackForString(instance_type)); |
| Goto(if_equal); |
| } |
| |
| BIND(&if_symbol); |
| { |
| CSA_ASSERT(this, IsSymbol(value)); |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kSymbol); |
| Goto(if_equal); |
| } |
| |
| BIND(&if_receiver); |
| { |
| CSA_ASSERT(this, IsJSReceiver(value)); |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kReceiver); |
| Goto(if_equal); |
| } |
| |
| BIND(&if_bigint); |
| { |
| CSA_ASSERT(this, IsBigInt(value)); |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kBigInt); |
| Goto(if_equal); |
| } |
| |
| BIND(&if_oddball); |
| { |
| CSA_ASSERT(this, IsOddball(value)); |
| Label if_boolean(this), if_not_boolean(this); |
| Branch(IsBooleanMap(value_map), &if_boolean, &if_not_boolean); |
| |
| BIND(&if_boolean); |
| { |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kAny); |
| Goto(if_equal); |
| } |
| |
| BIND(&if_not_boolean); |
| { |
| CSA_ASSERT(this, IsNullOrUndefined(value)); |
| CombineFeedback(var_type_feedback, |
| CompareOperationFeedback::kReceiverOrNullOrUndefined); |
| Goto(if_equal); |
| } |
| } |
| } else { |
| Goto(if_equal); |
| } |
| |
| BIND(&if_heapnumber); |
| { |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kNumber); |
| Node* number_value = LoadHeapNumberValue(value); |
| BranchIfFloat64IsNaN(number_value, if_notequal, if_equal); |
| } |
| |
| BIND(&if_smi); |
| { |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kSignedSmall); |
| Goto(if_equal); |
| } |
| } |
| |
| // ES6 section 7.2.12 Abstract Equality Comparison |
| Node* CodeStubAssembler::Equal(Node* left, Node* right, Node* context, |
| Variable* var_type_feedback) { |
| // This is a slightly optimized version of Object::Equals. Whenever you |
| // change something functionality wise in here, remember to update the |
| // Object::Equals method as well. |
| |
| Label if_equal(this), if_notequal(this), do_float_comparison(this), |
| do_right_stringtonumber(this, Label::kDeferred), end(this); |
| VARIABLE(result, MachineRepresentation::kTagged); |
| TVARIABLE(Float64T, var_left_float); |
| TVARIABLE(Float64T, var_right_float); |
| |
| // We can avoid code duplication by exploiting the fact that abstract equality |
| // is symmetric. |
| Label use_symmetry(this); |
| |
| // We might need to loop several times due to ToPrimitive and/or ToNumber |
| // conversions. |
| VARIABLE(var_left, MachineRepresentation::kTagged, left); |
| VARIABLE(var_right, MachineRepresentation::kTagged, right); |
| VariableList loop_variable_list({&var_left, &var_right}, zone()); |
| if (var_type_feedback != nullptr) { |
| // Initialize the type feedback to None. The current feedback will be |
| // combined with the previous feedback. |
| OverwriteFeedback(var_type_feedback, CompareOperationFeedback::kNone); |
| loop_variable_list.push_back(var_type_feedback); |
| } |
| Label loop(this, loop_variable_list); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| left = var_left.value(); |
| right = var_right.value(); |
| |
| Label if_notsame(this); |
| GotoIf(WordNotEqual(left, right), &if_notsame); |
| { |
| // {left} and {right} reference the exact same value, yet we need special |
| // treatment for HeapNumber, as NaN is not equal to NaN. |
| GenerateEqual_Same(left, &if_equal, &if_notequal, var_type_feedback); |
| } |
| |
| BIND(&if_notsame); |
| Label if_left_smi(this), if_left_not_smi(this); |
| Branch(TaggedIsSmi(left), &if_left_smi, &if_left_not_smi); |
| |
| BIND(&if_left_smi); |
| { |
| Label if_right_smi(this), if_right_not_smi(this); |
| Branch(TaggedIsSmi(right), &if_right_smi, &if_right_not_smi); |
| |
| BIND(&if_right_smi); |
| { |
| // We have already checked for {left} and {right} being the same value, |
| // so when we get here they must be different Smis. |
| CombineFeedback(var_type_feedback, |
| CompareOperationFeedback::kSignedSmall); |
| Goto(&if_notequal); |
| } |
| |
| BIND(&if_right_not_smi); |
| Node* right_map = LoadMap(right); |
| Label if_right_heapnumber(this), if_right_boolean(this), |
| if_right_bigint(this, Label::kDeferred), |
| if_right_receiver(this, Label::kDeferred); |
| GotoIf(IsHeapNumberMap(right_map), &if_right_heapnumber); |
| // {left} is Smi and {right} is not HeapNumber or Smi. |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind(SmiConstant(CompareOperationFeedback::kAny)); |
| } |
| GotoIf(IsBooleanMap(right_map), &if_right_boolean); |
| Node* right_type = LoadMapInstanceType(right_map); |
| GotoIf(IsStringInstanceType(right_type), &do_right_stringtonumber); |
| GotoIf(IsBigIntInstanceType(right_type), &if_right_bigint); |
| Branch(IsJSReceiverInstanceType(right_type), &if_right_receiver, |
| &if_notequal); |
| |
| BIND(&if_right_heapnumber); |
| { |
| var_left_float = SmiToFloat64(left); |
| var_right_float = LoadHeapNumberValue(right); |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kNumber); |
| Goto(&do_float_comparison); |
| } |
| |
| BIND(&if_right_boolean); |
| { |
| var_right.Bind(LoadObjectField(right, Oddball::kToNumberOffset)); |
| Goto(&loop); |
| } |
| |
| BIND(&if_right_bigint); |
| { |
| result.Bind(CallRuntime(Runtime::kBigIntEqualToNumber, |
| NoContextConstant(), right, left)); |
| Goto(&end); |
| } |
| |
| BIND(&if_right_receiver); |
| { |
| Callable callable = CodeFactory::NonPrimitiveToPrimitive(isolate()); |
| var_right.Bind(CallStub(callable, context, right)); |
| Goto(&loop); |
| } |
| } |
| |
| BIND(&if_left_not_smi); |
| { |
| GotoIf(TaggedIsSmi(right), &use_symmetry); |
| |
| Label if_left_symbol(this), if_left_number(this), if_left_string(this), |
| if_left_bigint(this, Label::kDeferred), if_left_oddball(this), |
| if_left_receiver(this); |
| |
| Node* left_map = LoadMap(left); |
| Node* right_map = LoadMap(right); |
| Node* left_type = LoadMapInstanceType(left_map); |
| Node* right_type = LoadMapInstanceType(right_map); |
| |
| GotoIf(IsStringInstanceType(left_type), &if_left_string); |
| GotoIf(IsSymbolInstanceType(left_type), &if_left_symbol); |
| GotoIf(IsHeapNumberInstanceType(left_type), &if_left_number); |
| GotoIf(IsOddballInstanceType(left_type), &if_left_oddball); |
| Branch(IsBigIntInstanceType(left_type), &if_left_bigint, |
| &if_left_receiver); |
| |
| BIND(&if_left_string); |
| { |
| GotoIfNot(IsStringInstanceType(right_type), &use_symmetry); |
| result.Bind(CallBuiltin(Builtins::kStringEqual, context, left, right)); |
| CombineFeedback(var_type_feedback, |
| SmiOr(CollectFeedbackForString(left_type), |
| CollectFeedbackForString(right_type))); |
| Goto(&end); |
| } |
| |
| BIND(&if_left_number); |
| { |
| Label if_right_not_number(this); |
| GotoIf(Word32NotEqual(left_type, right_type), &if_right_not_number); |
| |
| var_left_float = LoadHeapNumberValue(left); |
| var_right_float = LoadHeapNumberValue(right); |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kNumber); |
| Goto(&do_float_comparison); |
| |
| BIND(&if_right_not_number); |
| { |
| Label if_right_boolean(this); |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kAny)); |
| } |
| GotoIf(IsStringInstanceType(right_type), &do_right_stringtonumber); |
| GotoIf(IsBooleanMap(right_map), &if_right_boolean); |
| GotoIf(IsBigIntInstanceType(right_type), &use_symmetry); |
| Branch(IsJSReceiverInstanceType(right_type), &use_symmetry, |
| &if_notequal); |
| |
| BIND(&if_right_boolean); |
| { |
| var_right.Bind(LoadObjectField(right, Oddball::kToNumberOffset)); |
| Goto(&loop); |
| } |
| } |
| } |
| |
| BIND(&if_left_bigint); |
| { |
| Label if_right_heapnumber(this), if_right_bigint(this), |
| if_right_string(this), if_right_boolean(this); |
| GotoIf(IsHeapNumberMap(right_map), &if_right_heapnumber); |
| GotoIf(IsBigIntInstanceType(right_type), &if_right_bigint); |
| GotoIf(IsStringInstanceType(right_type), &if_right_string); |
| GotoIf(IsBooleanMap(right_map), &if_right_boolean); |
| Branch(IsJSReceiverInstanceType(right_type), &use_symmetry, |
| &if_notequal); |
| |
| BIND(&if_right_heapnumber); |
| { |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kAny)); |
| } |
| result.Bind(CallRuntime(Runtime::kBigIntEqualToNumber, |
| NoContextConstant(), left, right)); |
| Goto(&end); |
| } |
| |
| BIND(&if_right_bigint); |
| { |
| CombineFeedback(var_type_feedback, CompareOperationFeedback::kBigInt); |
| result.Bind(CallRuntime(Runtime::kBigIntEqualToBigInt, |
| NoContextConstant(), left, right)); |
| Goto(&end); |
| } |
| |
| BIND(&if_right_string); |
| { |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kAny)); |
| } |
| result.Bind(CallRuntime(Runtime::kBigIntEqualToString, |
| NoContextConstant(), left, right)); |
| Goto(&end); |
| } |
| |
| BIND(&if_right_boolean); |
| { |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kAny)); |
| } |
| var_right.Bind(LoadObjectField(right, Oddball::kToNumberOffset)); |
| Goto(&loop); |
| } |
| } |
| |
| BIND(&if_left_oddball); |
| { |
| Label if_left_boolean(this), if_left_not_boolean(this); |
| Branch(IsBooleanMap(left_map), &if_left_boolean, &if_left_not_boolean); |
| |
| BIND(&if_left_not_boolean); |
| { |
| // {left} is either Null or Undefined. Check if {right} is |
| // undetectable (which includes Null and Undefined). |
| Label if_right_undetectable(this), if_right_not_undetectable(this); |
| Branch(IsUndetectableMap(right_map), &if_right_undetectable, |
| &if_right_not_undetectable); |
| |
| BIND(&if_right_undetectable); |
| { |
| if (var_type_feedback != nullptr) { |
| // If {right} is undetectable, it must be either also |
| // Null or Undefined, or a Receiver (aka document.all). |
| var_type_feedback->Bind(SmiConstant( |
| CompareOperationFeedback::kReceiverOrNullOrUndefined)); |
| } |
| Goto(&if_equal); |
| } |
| |
| BIND(&if_right_not_undetectable); |
| { |
| if (var_type_feedback != nullptr) { |
| // Track whether {right} is Null, Undefined or Receiver. |
| var_type_feedback->Bind(SmiConstant( |
| CompareOperationFeedback::kReceiverOrNullOrUndefined)); |
| GotoIf(IsJSReceiverInstanceType(right_type), &if_notequal); |
| GotoIfNot(IsBooleanMap(right_map), &if_notequal); |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kAny)); |
| } |
| Goto(&if_notequal); |
| } |
| } |
| |
| BIND(&if_left_boolean); |
| { |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kAny)); |
| } |
| |
| // If {right} is a Boolean too, it must be a different Boolean. |
| GotoIf(WordEqual(right_map, left_map), &if_notequal); |
| |
| // Otherwise, convert {left} to number and try again. |
| var_left.Bind(LoadObjectField(left, Oddball::kToNumberOffset)); |
| Goto(&loop); |
| } |
| } |
| |
| BIND(&if_left_symbol); |
| { |
| Label if_right_receiver(this); |
| GotoIf(IsJSReceiverInstanceType(right_type), &if_right_receiver); |
| // {right} is not a JSReceiver and also not the same Symbol as {left}, |
| // so the result is "not equal". |
| if (var_type_feedback != nullptr) { |
| Label if_right_symbol(this); |
| GotoIf(IsSymbolInstanceType(right_type), &if_right_symbol); |
| var_type_feedback->Bind(SmiConstant(CompareOperationFeedback::kAny)); |
| Goto(&if_notequal); |
| |
| BIND(&if_right_symbol); |
| { |
| CombineFeedback(var_type_feedback, |
| CompareOperationFeedback::kSymbol); |
| Goto(&if_notequal); |
| } |
| } else { |
| Goto(&if_notequal); |
| } |
| |
| BIND(&if_right_receiver); |
| { |
| // {left} is a Primitive and {right} is a JSReceiver, so swapping |
| // the order is not observable. |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kAny)); |
| } |
| Goto(&use_symmetry); |
| } |
| } |
| |
| BIND(&if_left_receiver); |
| { |
| CSA_ASSERT(this, IsJSReceiverInstanceType(left_type)); |
| Label if_right_receiver(this), if_right_not_receiver(this); |
| Branch(IsJSReceiverInstanceType(right_type), &if_right_receiver, |
| &if_right_not_receiver); |
| |
| BIND(&if_right_receiver); |
| { |
| // {left} and {right} are different JSReceiver references. |
| CombineFeedback(var_type_feedback, |
| CompareOperationFeedback::kReceiver); |
| Goto(&if_notequal); |
| } |
| |
| BIND(&if_right_not_receiver); |
| { |
| // Check if {right} is undetectable, which means it must be Null |
| // or Undefined, since we already ruled out Receiver for {right}. |
| Label if_right_undetectable(this), |
| if_right_not_undetectable(this, Label::kDeferred); |
| Branch(IsUndetectableMap(right_map), &if_right_undetectable, |
| &if_right_not_undetectable); |
| |
| BIND(&if_right_undetectable); |
| { |
| // When we get here, {right} must be either Null or Undefined. |
| CSA_ASSERT(this, IsNullOrUndefined(right)); |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind(SmiConstant( |
| CompareOperationFeedback::kReceiverOrNullOrUndefined)); |
| } |
| Branch(IsUndetectableMap(left_map), &if_equal, &if_notequal); |
| } |
| |
| BIND(&if_right_not_undetectable); |
| { |
| // {right} is a Primitive, and neither Null or Undefined; |
| // convert {left} to Primitive too. |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kAny)); |
| } |
| Callable callable = CodeFactory::NonPrimitiveToPrimitive(isolate()); |
| var_left.Bind(CallStub(callable, context, left)); |
| Goto(&loop); |
| } |
| } |
| } |
| } |
| |
| BIND(&do_right_stringtonumber); |
| { |
| var_right.Bind(CallBuiltin(Builtins::kStringToNumber, context, right)); |
| Goto(&loop); |
| } |
| |
| BIND(&use_symmetry); |
| { |
| var_left.Bind(right); |
| var_right.Bind(left); |
| Goto(&loop); |
| } |
| } |
| |
| BIND(&do_float_comparison); |
| { |
| Branch(Float64Equal(var_left_float.value(), var_right_float.value()), |
| &if_equal, &if_notequal); |
| } |
| |
| BIND(&if_equal); |
| { |
| result.Bind(TrueConstant()); |
| Goto(&end); |
| } |
| |
| BIND(&if_notequal); |
| { |
| result.Bind(FalseConstant()); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return result.value(); |
| } |
| |
| Node* CodeStubAssembler::StrictEqual(Node* lhs, Node* rhs, |
| Variable* var_type_feedback) { |
| // Pseudo-code for the algorithm below: |
| // |
| // if (lhs == rhs) { |
| // if (lhs->IsHeapNumber()) return HeapNumber::cast(lhs)->value() != NaN; |
| // return true; |
| // } |
| // if (!lhs->IsSmi()) { |
| // if (lhs->IsHeapNumber()) { |
| // if (rhs->IsSmi()) { |
| // return Smi::ToInt(rhs) == HeapNumber::cast(lhs)->value(); |
| // } else if (rhs->IsHeapNumber()) { |
| // return HeapNumber::cast(rhs)->value() == |
| // HeapNumber::cast(lhs)->value(); |
| // } else { |
| // return false; |
| // } |
| // } else { |
| // if (rhs->IsSmi()) { |
| // return false; |
| // } else { |
| // if (lhs->IsString()) { |
| // if (rhs->IsString()) { |
| // return %StringEqual(lhs, rhs); |
| // } else { |
| // return false; |
| // } |
| // } else if (lhs->IsBigInt()) { |
| // if (rhs->IsBigInt()) { |
| // return %BigIntEqualToBigInt(lhs, rhs); |
| // } else { |
| // return false; |
| // } |
| // } else { |
| // return false; |
| // } |
| // } |
| // } |
| // } else { |
| // if (rhs->IsSmi()) { |
| // return false; |
| // } else { |
| // if (rhs->IsHeapNumber()) { |
| // return Smi::ToInt(lhs) == HeapNumber::cast(rhs)->value(); |
| // } else { |
| // return false; |
| // } |
| // } |
| // } |
| |
| Label if_equal(this), if_notequal(this), end(this); |
| VARIABLE(result, MachineRepresentation::kTagged); |
| |
| // Check if {lhs} and {rhs} refer to the same object. |
| Label if_same(this), if_notsame(this); |
| Branch(WordEqual(lhs, rhs), &if_same, &if_notsame); |
| |
| BIND(&if_same); |
| { |
| // The {lhs} and {rhs} reference the exact same value, yet we need special |
| // treatment for HeapNumber, as NaN is not equal to NaN. |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind(SmiConstant(CompareOperationFeedback::kNone)); |
| } |
| GenerateEqual_Same(lhs, &if_equal, &if_notequal, var_type_feedback); |
| } |
| |
| BIND(&if_notsame); |
| { |
| // The {lhs} and {rhs} reference different objects, yet for Smi, HeapNumber, |
| // BigInt and String they can still be considered equal. |
| |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind(SmiConstant(CompareOperationFeedback::kAny)); |
| } |
| |
| // Check if {lhs} is a Smi or a HeapObject. |
| Label if_lhsissmi(this), if_lhsisnotsmi(this); |
| Branch(TaggedIsSmi(lhs), &if_lhsissmi, &if_lhsisnotsmi); |
| |
| BIND(&if_lhsisnotsmi); |
| { |
| // Load the map of {lhs}. |
| Node* lhs_map = LoadMap(lhs); |
| |
| // Check if {lhs} is a HeapNumber. |
| Label if_lhsisnumber(this), if_lhsisnotnumber(this); |
| Branch(IsHeapNumberMap(lhs_map), &if_lhsisnumber, &if_lhsisnotnumber); |
| |
| BIND(&if_lhsisnumber); |
| { |
| // Check if {rhs} is a Smi or a HeapObject. |
| Label if_rhsissmi(this), if_rhsisnotsmi(this); |
| Branch(TaggedIsSmi(rhs), &if_rhsissmi, &if_rhsisnotsmi); |
| |
| BIND(&if_rhsissmi); |
| { |
| // Convert {lhs} and {rhs} to floating point values. |
| Node* lhs_value = LoadHeapNumberValue(lhs); |
| Node* rhs_value = SmiToFloat64(rhs); |
| |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kNumber)); |
| } |
| |
| // Perform a floating point comparison of {lhs} and {rhs}. |
| Branch(Float64Equal(lhs_value, rhs_value), &if_equal, &if_notequal); |
| } |
| |
| BIND(&if_rhsisnotsmi); |
| { |
| // Load the map of {rhs}. |
| Node* rhs_map = LoadMap(rhs); |
| |
| // Check if {rhs} is also a HeapNumber. |
| Label if_rhsisnumber(this), if_rhsisnotnumber(this); |
| Branch(IsHeapNumberMap(rhs_map), &if_rhsisnumber, &if_rhsisnotnumber); |
| |
| BIND(&if_rhsisnumber); |
| { |
| // Convert {lhs} and {rhs} to floating point values. |
| Node* lhs_value = LoadHeapNumberValue(lhs); |
| Node* rhs_value = LoadHeapNumberValue(rhs); |
| |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kNumber)); |
| } |
| |
| // Perform a floating point comparison of {lhs} and {rhs}. |
| Branch(Float64Equal(lhs_value, rhs_value), &if_equal, &if_notequal); |
| } |
| |
| BIND(&if_rhsisnotnumber); |
| Goto(&if_notequal); |
| } |
| } |
| |
| BIND(&if_lhsisnotnumber); |
| { |
| // Check if {rhs} is a Smi or a HeapObject. |
| Label if_rhsissmi(this), if_rhsisnotsmi(this); |
| Branch(TaggedIsSmi(rhs), &if_rhsissmi, &if_rhsisnotsmi); |
| |
| BIND(&if_rhsissmi); |
| Goto(&if_notequal); |
| |
| BIND(&if_rhsisnotsmi); |
| { |
| // Load the instance type of {lhs}. |
| Node* lhs_instance_type = LoadMapInstanceType(lhs_map); |
| |
| // Check if {lhs} is a String. |
| Label if_lhsisstring(this), if_lhsisnotstring(this); |
| Branch(IsStringInstanceType(lhs_instance_type), &if_lhsisstring, |
| &if_lhsisnotstring); |
| |
| BIND(&if_lhsisstring); |
| { |
| // Load the instance type of {rhs}. |
| Node* rhs_instance_type = LoadInstanceType(rhs); |
| |
| // Check if {rhs} is also a String. |
| Label if_rhsisstring(this, Label::kDeferred), |
| if_rhsisnotstring(this); |
| Branch(IsStringInstanceType(rhs_instance_type), &if_rhsisstring, |
| &if_rhsisnotstring); |
| |
| BIND(&if_rhsisstring); |
| { |
| if (var_type_feedback != nullptr) { |
| TNode<Smi> lhs_feedback = |
| CollectFeedbackForString(lhs_instance_type); |
| TNode<Smi> rhs_feedback = |
| CollectFeedbackForString(rhs_instance_type); |
| var_type_feedback->Bind(SmiOr(lhs_feedback, rhs_feedback)); |
| } |
| result.Bind(CallBuiltin(Builtins::kStringEqual, |
| NoContextConstant(), lhs, rhs)); |
| Goto(&end); |
| } |
| |
| BIND(&if_rhsisnotstring); |
| Goto(&if_notequal); |
| } |
| |
| BIND(&if_lhsisnotstring); |
| |
| // Check if {lhs} is a BigInt. |
| Label if_lhsisbigint(this), if_lhsisnotbigint(this); |
| Branch(IsBigIntInstanceType(lhs_instance_type), &if_lhsisbigint, |
| &if_lhsisnotbigint); |
| |
| BIND(&if_lhsisbigint); |
| { |
| // Load the instance type of {rhs}. |
| Node* rhs_instance_type = LoadInstanceType(rhs); |
| |
| // Check if {rhs} is also a BigInt. |
| Label if_rhsisbigint(this, Label::kDeferred), |
| if_rhsisnotbigint(this); |
| Branch(IsBigIntInstanceType(rhs_instance_type), &if_rhsisbigint, |
| &if_rhsisnotbigint); |
| |
| BIND(&if_rhsisbigint); |
| { |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kBigInt)); |
| } |
| result.Bind(CallRuntime(Runtime::kBigIntEqualToBigInt, |
| NoContextConstant(), lhs, rhs)); |
| Goto(&end); |
| } |
| |
| BIND(&if_rhsisnotbigint); |
| Goto(&if_notequal); |
| } |
| |
| BIND(&if_lhsisnotbigint); |
| if (var_type_feedback != nullptr) { |
| // Load the instance type of {rhs}. |
| Node* rhs_map = LoadMap(rhs); |
| Node* rhs_instance_type = LoadMapInstanceType(rhs_map); |
| |
| Label if_lhsissymbol(this), if_lhsisreceiver(this), |
| if_lhsisoddball(this); |
| GotoIf(IsJSReceiverInstanceType(lhs_instance_type), |
| &if_lhsisreceiver); |
| GotoIf(IsBooleanMap(lhs_map), &if_notequal); |
| GotoIf(IsOddballInstanceType(lhs_instance_type), &if_lhsisoddball); |
| Branch(IsSymbolInstanceType(lhs_instance_type), &if_lhsissymbol, |
| &if_notequal); |
| |
| BIND(&if_lhsisreceiver); |
| { |
| GotoIf(IsBooleanMap(rhs_map), &if_notequal); |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kReceiver)); |
| GotoIf(IsJSReceiverInstanceType(rhs_instance_type), &if_notequal); |
| var_type_feedback->Bind(SmiConstant( |
| CompareOperationFeedback::kReceiverOrNullOrUndefined)); |
| GotoIf(IsOddballInstanceType(rhs_instance_type), &if_notequal); |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kAny)); |
| Goto(&if_notequal); |
| } |
| |
| BIND(&if_lhsisoddball); |
| { |
| STATIC_ASSERT(LAST_PRIMITIVE_TYPE == ODDBALL_TYPE); |
| GotoIf(IsBooleanMap(rhs_map), &if_notequal); |
| GotoIf( |
| Int32LessThan(rhs_instance_type, Int32Constant(ODDBALL_TYPE)), |
| &if_notequal); |
| var_type_feedback->Bind(SmiConstant( |
| CompareOperationFeedback::kReceiverOrNullOrUndefined)); |
| Goto(&if_notequal); |
| } |
| |
| BIND(&if_lhsissymbol); |
| { |
| GotoIfNot(IsSymbolInstanceType(rhs_instance_type), &if_notequal); |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kSymbol)); |
| Goto(&if_notequal); |
| } |
| } else { |
| Goto(&if_notequal); |
| } |
| } |
| } |
| } |
| |
| BIND(&if_lhsissmi); |
| { |
| // We already know that {lhs} and {rhs} are not reference equal, and {lhs} |
| // is a Smi; so {lhs} and {rhs} can only be strictly equal if {rhs} is a |
| // HeapNumber with an equal floating point value. |
| |
| // Check if {rhs} is a Smi or a HeapObject. |
| Label if_rhsissmi(this), if_rhsisnotsmi(this); |
| Branch(TaggedIsSmi(rhs), &if_rhsissmi, &if_rhsisnotsmi); |
| |
| BIND(&if_rhsissmi); |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kSignedSmall)); |
| } |
| Goto(&if_notequal); |
| |
| BIND(&if_rhsisnotsmi); |
| { |
| // Load the map of the {rhs}. |
| Node* rhs_map = LoadMap(rhs); |
| |
| // The {rhs} could be a HeapNumber with the same value as {lhs}. |
| Label if_rhsisnumber(this), if_rhsisnotnumber(this); |
| Branch(IsHeapNumberMap(rhs_map), &if_rhsisnumber, &if_rhsisnotnumber); |
| |
| BIND(&if_rhsisnumber); |
| { |
| // Convert {lhs} and {rhs} to floating point values. |
| Node* lhs_value = SmiToFloat64(lhs); |
| Node* rhs_value = LoadHeapNumberValue(rhs); |
| |
| if (var_type_feedback != nullptr) { |
| var_type_feedback->Bind( |
| SmiConstant(CompareOperationFeedback::kNumber)); |
| } |
| |
| // Perform a floating point comparison of {lhs} and {rhs}. |
| Branch(Float64Equal(lhs_value, rhs_value), &if_equal, &if_notequal); |
| } |
| |
| BIND(&if_rhsisnotnumber); |
| Goto(&if_notequal); |
| } |
| } |
| } |
| |
| BIND(&if_equal); |
| { |
| result.Bind(TrueConstant()); |
| Goto(&end); |
| } |
| |
| BIND(&if_notequal); |
| { |
| result.Bind(FalseConstant()); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return result.value(); |
| } |
| |
| // ECMA#sec-samevalue |
| // This algorithm differs from the Strict Equality Comparison Algorithm in its |
| // treatment of signed zeroes and NaNs. |
| void CodeStubAssembler::BranchIfSameValue(Node* lhs, Node* rhs, Label* if_true, |
| Label* if_false) { |
| VARIABLE(var_lhs_value, MachineRepresentation::kFloat64); |
| VARIABLE(var_rhs_value, MachineRepresentation::kFloat64); |
| Label do_fcmp(this); |
| |
| // Immediately jump to {if_true} if {lhs} == {rhs}, because - unlike |
| // StrictEqual - SameValue considers two NaNs to be equal. |
| GotoIf(WordEqual(lhs, rhs), if_true); |
| |
| // Check if the {lhs} is a Smi. |
| Label if_lhsissmi(this), if_lhsisheapobject(this); |
| Branch(TaggedIsSmi(lhs), &if_lhsissmi, &if_lhsisheapobject); |
| |
| BIND(&if_lhsissmi); |
| { |
| // Since {lhs} is a Smi, the comparison can only yield true |
| // iff the {rhs} is a HeapNumber with the same float64 value. |
| Branch(TaggedIsSmi(rhs), if_false, [&] { |
| GotoIfNot(IsHeapNumber(rhs), if_false); |
| var_lhs_value.Bind(SmiToFloat64(lhs)); |
| var_rhs_value.Bind(LoadHeapNumberValue(rhs)); |
| Goto(&do_fcmp); |
| }); |
| } |
| |
| BIND(&if_lhsisheapobject); |
| { |
| // Check if the {rhs} is a Smi. |
| Branch(TaggedIsSmi(rhs), |
| [&] { |
| // Since {rhs} is a Smi, the comparison can only yield true |
| // iff the {lhs} is a HeapNumber with the same float64 value. |
| GotoIfNot(IsHeapNumber(lhs), if_false); |
| var_lhs_value.Bind(LoadHeapNumberValue(lhs)); |
| var_rhs_value.Bind(SmiToFloat64(rhs)); |
| Goto(&do_fcmp); |
| }, |
| [&] { |
| // Now this can only yield true if either both {lhs} and {rhs} are |
| // HeapNumbers with the same value, or both are Strings with the |
| // same character sequence, or both are BigInts with the same |
| // value. |
| Label if_lhsisheapnumber(this), if_lhsisstring(this), |
| if_lhsisbigint(this); |
| Node* const lhs_map = LoadMap(lhs); |
| GotoIf(IsHeapNumberMap(lhs_map), &if_lhsisheapnumber); |
| Node* const lhs_instance_type = LoadMapInstanceType(lhs_map); |
| GotoIf(IsStringInstanceType(lhs_instance_type), &if_lhsisstring); |
| Branch(IsBigIntInstanceType(lhs_instance_type), &if_lhsisbigint, |
| if_false); |
| |
| BIND(&if_lhsisheapnumber); |
| { |
| GotoIfNot(IsHeapNumber(rhs), if_false); |
| var_lhs_value.Bind(LoadHeapNumberValue(lhs)); |
| var_rhs_value.Bind(LoadHeapNumberValue(rhs)); |
| Goto(&do_fcmp); |
| } |
| |
| BIND(&if_lhsisstring); |
| { |
| // Now we can only yield true if {rhs} is also a String |
| // with the same sequence of characters. |
| GotoIfNot(IsString(rhs), if_false); |
| Node* const result = CallBuiltin(Builtins::kStringEqual, |
| NoContextConstant(), lhs, rhs); |
| Branch(IsTrue(result), if_true, if_false); |
| } |
| |
| BIND(&if_lhsisbigint); |
| { |
| GotoIfNot(IsBigInt(rhs), if_false); |
| Node* const result = CallRuntime(Runtime::kBigIntEqualToBigInt, |
| NoContextConstant(), lhs, rhs); |
| Branch(IsTrue(result), if_true, if_false); |
| } |
| }); |
| } |
| |
| BIND(&do_fcmp); |
| { |
| Node* const lhs_value = var_lhs_value.value(); |
| Node* const rhs_value = var_rhs_value.value(); |
| |
| Label if_equal(this), if_notequal(this); |
| Branch(Float64Equal(lhs_value, rhs_value), &if_equal, &if_notequal); |
| |
| BIND(&if_equal); |
| { |
| // We still need to handle the case when {lhs} and {rhs} are -0.0 and |
| // 0.0 (or vice versa). Compare the high word to |
| // distinguish between the two. |
| Node* const lhs_hi_word = Float64ExtractHighWord32(lhs_value); |
| Node* const rhs_hi_word = Float64ExtractHighWord32(rhs_value); |
| |
| // If x is +0 and y is -0, return false. |
| // If x is -0 and y is +0, return false. |
| Branch(Word32Equal(lhs_hi_word, rhs_hi_word), if_true, if_false); |
| } |
| |
| BIND(&if_notequal); |
| { |
| // Return true iff both {rhs} and {lhs} are NaN. |
| GotoIf(Float64Equal(lhs_value, lhs_value), if_false); |
| Branch(Float64Equal(rhs_value, rhs_value), if_false, if_true); |
| } |
| } |
| } |
| |
| TNode<Oddball> CodeStubAssembler::HasProperty(SloppyTNode<Context> context, |
| SloppyTNode<Object> object, |
| SloppyTNode<Object> key, |
| HasPropertyLookupMode mode) { |
| Label call_runtime(this, Label::kDeferred), return_true(this), |
| return_false(this), end(this), if_proxy(this, Label::kDeferred); |
| |
| CodeStubAssembler::LookupInHolder lookup_property_in_holder = |
| [this, &return_true](Node* receiver, Node* holder, Node* holder_map, |
| Node* holder_instance_type, Node* unique_name, |
| Label* next_holder, Label* if_bailout) { |
| TryHasOwnProperty(holder, holder_map, holder_instance_type, unique_name, |
| &return_true, next_holder, if_bailout); |
| }; |
| |
| CodeStubAssembler::LookupInHolder lookup_element_in_holder = |
| [this, &return_true, &return_false]( |
| Node* receiver, Node* holder, Node* holder_map, |
| Node* holder_instance_type, Node* index, Label* next_holder, |
| Label* if_bailout) { |
| TryLookupElement(holder, holder_map, holder_instance_type, index, |
| &return_true, &return_false, next_holder, if_bailout); |
| }; |
| |
| TryPrototypeChainLookup(object, key, lookup_property_in_holder, |
| lookup_element_in_holder, &return_false, |
| &call_runtime, &if_proxy); |
| |
| TVARIABLE(Oddball, result); |
| |
| BIND(&if_proxy); |
| { |
| TNode<Name> name = CAST(CallBuiltin(Builtins::kToName, context, key)); |
| switch (mode) { |
| case kHasProperty: |
| GotoIf(IsPrivateSymbol(name), &return_false); |
| |
| result = CAST( |
| CallBuiltin(Builtins::kProxyHasProperty, context, object, name)); |
| Goto(&end); |
| break; |
| case kForInHasProperty: |
| Goto(&call_runtime); |
| break; |
| } |
| } |
| |
| BIND(&return_true); |
| { |
| result = TrueConstant(); |
| Goto(&end); |
| } |
| |
| BIND(&return_false); |
| { |
| result = FalseConstant(); |
| Goto(&end); |
| } |
| |
| BIND(&call_runtime); |
| { |
| Runtime::FunctionId fallback_runtime_function_id; |
| switch (mode) { |
| case kHasProperty: |
| fallback_runtime_function_id = Runtime::kHasProperty; |
| break; |
| case kForInHasProperty: |
| fallback_runtime_function_id = Runtime::kForInHasProperty; |
| break; |
| } |
| |
| result = |
| CAST(CallRuntime(fallback_runtime_function_id, context, object, key)); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| CSA_ASSERT(this, IsBoolean(result.value())); |
| return result.value(); |
| } |
| |
| Node* CodeStubAssembler::Typeof(Node* value) { |
| VARIABLE(result_var, MachineRepresentation::kTagged); |
| |
| Label return_number(this, Label::kDeferred), if_oddball(this), |
| return_function(this), return_undefined(this), return_object(this), |
| return_string(this), return_bigint(this), return_result(this); |
| |
| GotoIf(TaggedIsSmi(value), &return_number); |
| |
| Node* map = LoadMap(value); |
| |
| GotoIf(IsHeapNumberMap(map), &return_number); |
| |
| Node* instance_type = LoadMapInstanceType(map); |
| |
| GotoIf(InstanceTypeEqual(instance_type, ODDBALL_TYPE), &if_oddball); |
| |
| Node* callable_or_undetectable_mask = Word32And( |
| LoadMapBitField(map), |
| Int32Constant(Map::IsCallableBit::kMask | Map::IsUndetectableBit::kMask)); |
| |
| GotoIf(Word32Equal(callable_or_undetectable_mask, |
| Int32Constant(Map::IsCallableBit::kMask)), |
| &return_function); |
| |
| GotoIfNot(Word32Equal(callable_or_undetectable_mask, Int32Constant(0)), |
| &return_undefined); |
| |
| GotoIf(IsJSReceiverInstanceType(instance_type), &return_object); |
| |
| GotoIf(IsStringInstanceType(instance_type), &return_string); |
| |
| GotoIf(IsBigIntInstanceType(instance_type), &return_bigint); |
| |
| CSA_ASSERT(this, InstanceTypeEqual(instance_type, SYMBOL_TYPE)); |
| result_var.Bind(HeapConstant(isolate()->factory()->symbol_string())); |
| Goto(&return_result); |
| |
| BIND(&return_number); |
| { |
| result_var.Bind(HeapConstant(isolate()->factory()->number_string())); |
| Goto(&return_result); |
| } |
| |
| BIND(&if_oddball); |
| { |
| Node* type = LoadObjectField(value, Oddball::kTypeOfOffset); |
| result_var.Bind(type); |
| Goto(&return_result); |
| } |
| |
| BIND(&return_function); |
| { |
| result_var.Bind(HeapConstant(isolate()->factory()->function_string())); |
| Goto(&return_result); |
| } |
| |
| BIND(&return_undefined); |
| { |
| result_var.Bind(HeapConstant(isolate()->factory()->undefined_string())); |
| Goto(&return_result); |
| } |
| |
| BIND(&return_object); |
| { |
| result_var.Bind(HeapConstant(isolate()->factory()->object_string())); |
| Goto(&return_result); |
| } |
| |
| BIND(&return_string); |
| { |
| result_var.Bind(HeapConstant(isolate()->factory()->string_string())); |
| Goto(&return_result); |
| } |
| |
| BIND(&return_bigint); |
| { |
| result_var.Bind(HeapConstant(isolate()->factory()->bigint_string())); |
| Goto(&return_result); |
| } |
| |
| BIND(&return_result); |
| return result_var.value(); |
| } |
| |
| TNode<Object> CodeStubAssembler::GetSuperConstructor( |
| SloppyTNode<Context> context, SloppyTNode<JSFunction> active_function) { |
| Label is_not_constructor(this, Label::kDeferred), out(this); |
| TVARIABLE(Object, result); |
| |
| TNode<Map> map = LoadMap(active_function); |
| TNode<Object> prototype = LoadMapPrototype(map); |
| TNode<Map> prototype_map = LoadMap(CAST(prototype)); |
| GotoIfNot(IsConstructorMap(prototype_map), &is_not_constructor); |
| |
| result = prototype; |
| Goto(&out); |
| |
| BIND(&is_not_constructor); |
| { |
| CallRuntime(Runtime::kThrowNotSuperConstructor, context, prototype, |
| active_function); |
| Unreachable(); |
| } |
| |
| BIND(&out); |
| return result.value(); |
| } |
| |
| TNode<JSReceiver> CodeStubAssembler::SpeciesConstructor( |
| SloppyTNode<Context> context, SloppyTNode<Object> object, |
| SloppyTNode<JSReceiver> default_constructor) { |
| Isolate* isolate = this->isolate(); |
| TVARIABLE(JSReceiver, var_result, default_constructor); |
| |
| // 2. Let C be ? Get(O, "constructor"). |
| TNode<Object> constructor = |
| GetProperty(context, object, isolate->factory()->constructor_string()); |
| |
| // 3. If C is undefined, return defaultConstructor. |
| Label out(this); |
| GotoIf(IsUndefined(constructor), &out); |
| |
| // 4. If Type(C) is not Object, throw a TypeError exception. |
| ThrowIfNotJSReceiver(context, constructor, |
| MessageTemplate::kConstructorNotReceiver); |
| |
| // 5. Let S be ? Get(C, @@species). |
| TNode<Object> species = |
| GetProperty(context, constructor, isolate->factory()->species_symbol()); |
| |
| // 6. If S is either undefined or null, return defaultConstructor. |
| GotoIf(IsNullOrUndefined(species), &out); |
| |
| // 7. If IsConstructor(S) is true, return S. |
| Label throw_error(this); |
| GotoIf(TaggedIsSmi(species), &throw_error); |
| GotoIfNot(IsConstructorMap(LoadMap(CAST(species))), &throw_error); |
| var_result = CAST(species); |
| Goto(&out); |
| |
| // 8. Throw a TypeError exception. |
| BIND(&throw_error); |
| ThrowTypeError(context, MessageTemplate::kSpeciesNotConstructor); |
| |
| BIND(&out); |
| return var_result.value(); |
| } |
| |
| Node* CodeStubAssembler::InstanceOf(Node* object, Node* callable, |
| Node* context) { |
| VARIABLE(var_result, MachineRepresentation::kTagged); |
| Label if_notcallable(this, Label::kDeferred), |
| if_notreceiver(this, Label::kDeferred), if_otherhandler(this), |
| if_nohandler(this, Label::kDeferred), return_true(this), |
| return_false(this), return_result(this, &var_result); |
| |
| // Ensure that the {callable} is actually a JSReceiver. |
| GotoIf(TaggedIsSmi(callable), &if_notreceiver); |
| GotoIfNot(IsJSReceiver(callable), &if_notreceiver); |
| |
| // Load the @@hasInstance property from {callable}. |
| Node* inst_of_handler = |
| GetProperty(context, callable, HasInstanceSymbolConstant()); |
| |
| // Optimize for the likely case where {inst_of_handler} is the builtin |
| // Function.prototype[@@hasInstance] method, and emit a direct call in |
| // that case without any additional checking. |
| Node* native_context = LoadNativeContext(context); |
| Node* function_has_instance = |
| LoadContextElement(native_context, Context::FUNCTION_HAS_INSTANCE_INDEX); |
| GotoIfNot(WordEqual(inst_of_handler, function_has_instance), |
| &if_otherhandler); |
| { |
| // Call to Function.prototype[@@hasInstance] directly. |
| Callable builtin(BUILTIN_CODE(isolate(), FunctionPrototypeHasInstance), |
| CallTrampolineDescriptor{}); |
| Node* result = CallJS(builtin, context, inst_of_handler, callable, object); |
| var_result.Bind(result); |
| Goto(&return_result); |
| } |
| |
| BIND(&if_otherhandler); |
| { |
| // Check if there's actually an {inst_of_handler}. |
| GotoIf(IsNull(inst_of_handler), &if_nohandler); |
| GotoIf(IsUndefined(inst_of_handler), &if_nohandler); |
| |
| // Call the {inst_of_handler} for {callable} and {object}. |
| Node* result = CallJS( |
| CodeFactory::Call(isolate(), ConvertReceiverMode::kNotNullOrUndefined), |
| context, inst_of_handler, callable, object); |
| |
| // Convert the {result} to a Boolean. |
| BranchIfToBooleanIsTrue(result, &return_true, &return_false); |
| } |
| |
| BIND(&if_nohandler); |
| { |
| // Ensure that the {callable} is actually Callable. |
| GotoIfNot(IsCallable(callable), &if_notcallable); |
| |
| // Use the OrdinaryHasInstance algorithm. |
| Node* result = |
| CallBuiltin(Builtins::kOrdinaryHasInstance, context, callable, object); |
| var_result.Bind(result); |
| Goto(&return_result); |
| } |
| |
| BIND(&if_notcallable); |
| { ThrowTypeError(context, MessageTemplate::kNonCallableInInstanceOfCheck); } |
| |
| BIND(&if_notreceiver); |
| { ThrowTypeError(context, MessageTemplate::kNonObjectInInstanceOfCheck); } |
| |
| BIND(&return_true); |
| var_result.Bind(TrueConstant()); |
| Goto(&return_result); |
| |
| BIND(&return_false); |
| var_result.Bind(FalseConstant()); |
| Goto(&return_result); |
| |
| BIND(&return_result); |
| return var_result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::NumberInc(SloppyTNode<Number> value) { |
| TVARIABLE(Number, var_result); |
| TVARIABLE(Float64T, var_finc_value); |
| Label if_issmi(this), if_isnotsmi(this), do_finc(this), end(this); |
| Branch(TaggedIsSmi(value), &if_issmi, &if_isnotsmi); |
| |
| BIND(&if_issmi); |
| { |
| Label if_overflow(this); |
| TNode<Smi> smi_value = CAST(value); |
| TNode<Smi> one = SmiConstant(1); |
| var_result = TrySmiAdd(smi_value, one, &if_overflow); |
| Goto(&end); |
| |
| BIND(&if_overflow); |
| { |
| var_finc_value = SmiToFloat64(smi_value); |
| Goto(&do_finc); |
| } |
| } |
| |
| BIND(&if_isnotsmi); |
| { |
| TNode<HeapNumber> heap_number_value = CAST(value); |
| |
| // Load the HeapNumber value. |
| var_finc_value = LoadHeapNumberValue(heap_number_value); |
| Goto(&do_finc); |
| } |
| |
| BIND(&do_finc); |
| { |
| TNode<Float64T> finc_value = var_finc_value.value(); |
| TNode<Float64T> one = Float64Constant(1.0); |
| TNode<Float64T> finc_result = Float64Add(finc_value, one); |
| var_result = AllocateHeapNumberWithValue(finc_result); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::NumberDec(SloppyTNode<Number> value) { |
| TVARIABLE(Number, var_result); |
| TVARIABLE(Float64T, var_fdec_value); |
| Label if_issmi(this), if_isnotsmi(this), do_fdec(this), end(this); |
| Branch(TaggedIsSmi(value), &if_issmi, &if_isnotsmi); |
| |
| BIND(&if_issmi); |
| { |
| TNode<Smi> smi_value = CAST(value); |
| TNode<Smi> one = SmiConstant(1); |
| Label if_overflow(this); |
| var_result = TrySmiSub(smi_value, one, &if_overflow); |
| Goto(&end); |
| |
| BIND(&if_overflow); |
| { |
| var_fdec_value = SmiToFloat64(smi_value); |
| Goto(&do_fdec); |
| } |
| } |
| |
| BIND(&if_isnotsmi); |
| { |
| TNode<HeapNumber> heap_number_value = CAST(value); |
| |
| // Load the HeapNumber value. |
| var_fdec_value = LoadHeapNumberValue(heap_number_value); |
| Goto(&do_fdec); |
| } |
| |
| BIND(&do_fdec); |
| { |
| TNode<Float64T> fdec_value = var_fdec_value.value(); |
| TNode<Float64T> minus_one = Float64Constant(-1.0); |
| TNode<Float64T> fdec_result = Float64Add(fdec_value, minus_one); |
| var_result = AllocateHeapNumberWithValue(fdec_result); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::NumberAdd(SloppyTNode<Number> a, |
| SloppyTNode<Number> b) { |
| TVARIABLE(Number, var_result); |
| Label float_add(this, Label::kDeferred), end(this); |
| GotoIf(TaggedIsNotSmi(a), &float_add); |
| GotoIf(TaggedIsNotSmi(b), &float_add); |
| |
| // Try fast Smi addition first. |
| var_result = TrySmiAdd(CAST(a), CAST(b), &float_add); |
| Goto(&end); |
| |
| BIND(&float_add); |
| { |
| var_result = ChangeFloat64ToTagged( |
| Float64Add(ChangeNumberToFloat64(a), ChangeNumberToFloat64(b))); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| TNode<Number> CodeStubAssembler::NumberSub(SloppyTNode<Number> a, |
| SloppyTNode<Number> b) { |
| TVARIABLE(Number, var_result); |
| Label float_sub(this, Label::kDeferred), end(this); |
| GotoIf(TaggedIsNotSmi(a), &float_sub); |
| GotoIf(TaggedIsNotSmi(b), &float_sub); |
| |
| // Try fast Smi subtraction first. |
| var_result = TrySmiSub(CAST(a), CAST(b), &float_sub); |
| Goto(&end); |
| |
| BIND(&float_sub); |
| { |
| var_result = ChangeFloat64ToTagged( |
| Float64Sub(ChangeNumberToFloat64(a), ChangeNumberToFloat64(b))); |
| Goto(&end); |
| } |
| |
| BIND(&end); |
| return var_result.value(); |
| } |
| |
| void CodeStubAssembler::GotoIfNotNumber(Node* input, Label* is_not_number) { |
| Label is_number(this); |
| GotoIf(TaggedIsSmi(input), &is_number); |
| Branch(IsHeapNumber(input), &is_number, is_not_number); |
| BIND(&is_number); |
| } |
| |
| void CodeStubAssembler::GotoIfNumber(Node* input, Label* is_number) { |
| GotoIf(TaggedIsSmi(input), is_number); |
| GotoIf(IsHeapNumber(input), is_number); |
| } |
| |
| TNode<Number> CodeStubAssembler::BitwiseOp(Node* left32, Node* right32, |
| Operation bitwise_op) { |
| switch (bitwise_op) { |
| case Operation::kBitwiseAnd: |
| return ChangeInt32ToTagged(Signed(Word32And(left32, right32))); |
| case Operation::kBitwiseOr: |
| return ChangeInt32ToTagged(Signed(Word32Or(left32, right32))); |
| case Operation::kBitwiseXor: |
| return ChangeInt32ToTagged(Signed(Word32Xor(left32, right32))); |
| case Operation::kShiftLeft: |
| if (!Word32ShiftIsSafe()) { |
| right32 = Word32And(right32, Int32Constant(0x1F)); |
| } |
| return ChangeInt32ToTagged(Signed(Word32Shl(left32, right32))); |
| case Operation::kShiftRight: |
| if (!Word32ShiftIsSafe()) { |
| right32 = Word32And(right32, Int32Constant(0x1F)); |
| } |
| return ChangeInt32ToTagged(Signed(Word32Sar(left32, right32))); |
| case Operation::kShiftRightLogical: |
| if (!Word32ShiftIsSafe()) { |
| right32 = Word32And(right32, Int32Constant(0x1F)); |
| } |
| return ChangeUint32ToTagged(Unsigned(Word32Shr(left32, right32))); |
| default: |
| break; |
| } |
| UNREACHABLE(); |
| } |
| |
| // ES #sec-createarrayiterator |
| TNode<JSArrayIterator> CodeStubAssembler::CreateArrayIterator( |
| TNode<Context> context, TNode<Object> object, IterationKind kind) { |
| TNode<Context> native_context = LoadNativeContext(context); |
| TNode<Map> iterator_map = CAST(LoadContextElement( |
| native_context, Context::INITIAL_ARRAY_ITERATOR_MAP_INDEX)); |
| Node* iterator = Allocate(JSArrayIterator::kSize); |
| StoreMapNoWriteBarrier(iterator, iterator_map); |
| StoreObjectFieldRoot(iterator, JSArrayIterator::kPropertiesOrHashOffset, |
| RootIndex::kEmptyFixedArray); |
| StoreObjectFieldRoot(iterator, JSArrayIterator::kElementsOffset, |
| RootIndex::kEmptyFixedArray); |
| StoreObjectFieldNoWriteBarrier( |
| iterator, JSArrayIterator::kIteratedObjectOffset, object); |
| StoreObjectFieldNoWriteBarrier(iterator, JSArrayIterator::kNextIndexOffset, |
| SmiConstant(0)); |
| StoreObjectFieldNoWriteBarrier( |
| iterator, JSArrayIterator::kKindOffset, |
| SmiConstant(Smi::FromInt(static_cast<int>(kind)))); |
| return CAST(iterator); |
| } |
| |
| Node* CodeStubAssembler::AllocateJSIteratorResult(Node* context, Node* value, |
| Node* done) { |
| CSA_ASSERT(this, IsBoolean(done)); |
| Node* native_context = LoadNativeContext(context); |
| Node* map = |
| LoadContextElement(native_context, Context::ITERATOR_RESULT_MAP_INDEX); |
| Node* result = Allocate(JSIteratorResult::kSize); |
| StoreMapNoWriteBarrier(result, map); |
| StoreObjectFieldRoot(result, JSIteratorResult::kPropertiesOrHashOffset, |
| RootIndex::kEmptyFixedArray); |
| StoreObjectFieldRoot(result, JSIteratorResult::kElementsOffset, |
| RootIndex::kEmptyFixedArray); |
| StoreObjectFieldNoWriteBarrier(result, JSIteratorResult::kValueOffset, value); |
| StoreObjectFieldNoWriteBarrier(result, JSIteratorResult::kDoneOffset, done); |
| return result; |
| } |
| |
| Node* CodeStubAssembler::AllocateJSIteratorResultForEntry(Node* context, |
| Node* key, |
| Node* value) { |
| Node* native_context = LoadNativeContext(context); |
| Node* length = SmiConstant(2); |
| int const elements_size = FixedArray::SizeFor(2); |
| TNode<FixedArray> elements = UncheckedCast<FixedArray>( |
| Allocate(elements_size + JSArray::kSize + JSIteratorResult::kSize)); |
| StoreObjectFieldRoot(elements, FixedArray::kMapOffset, |
| RootIndex::kFixedArrayMap); |
| StoreObjectFieldNoWriteBarrier(elements, FixedArray::kLengthOffset, length); |
| StoreFixedArrayElement(elements, 0, key); |
| StoreFixedArrayElement(elements, 1, value); |
| Node* array_map = LoadContextElement( |
| native_context, Context::JS_ARRAY_PACKED_ELEMENTS_MAP_INDEX); |
| TNode<HeapObject> array = InnerAllocate(elements, elements_size); |
| StoreMapNoWriteBarrier(array, array_map); |
| StoreObjectFieldRoot(array, JSArray::kPropertiesOrHashOffset, |
| RootIndex::kEmptyFixedArray); |
| StoreObjectFieldNoWriteBarrier(array, JSArray::kElementsOffset, elements); |
| StoreObjectFieldNoWriteBarrier(array, JSArray::kLengthOffset, length); |
| Node* iterator_map = |
| LoadContextElement(native_context, Context::ITERATOR_RESULT_MAP_INDEX); |
| TNode<HeapObject> result = InnerAllocate(array, JSArray::kSize); |
| StoreMapNoWriteBarrier(result, iterator_map); |
| StoreObjectFieldRoot(result, JSIteratorResult::kPropertiesOrHashOffset, |
| RootIndex::kEmptyFixedArray); |
| StoreObjectFieldRoot(result, JSIteratorResult::kElementsOffset, |
| RootIndex::kEmptyFixedArray); |
| StoreObjectFieldNoWriteBarrier(result, JSIteratorResult::kValueOffset, array); |
| StoreObjectFieldRoot(result, JSIteratorResult::kDoneOffset, |
| RootIndex::kFalseValue); |
| return result; |
| } |
| |
| TNode<JSReceiver> CodeStubAssembler::ArraySpeciesCreate(TNode<Context> context, |
| TNode<Object> o, |
| TNode<Number> len) { |
| TNode<JSReceiver> constructor = |
| CAST(CallRuntime(Runtime::kArraySpeciesConstructor, context, o)); |
| return Construct(context, constructor, len); |
| } |
| |
| Node* CodeStubAssembler::IsDetachedBuffer(Node* buffer) { |
| CSA_ASSERT(this, HasInstanceType(buffer, JS_ARRAY_BUFFER_TYPE)); |
| TNode<Uint32T> buffer_bit_field = LoadJSArrayBufferBitField(CAST(buffer)); |
| return IsSetWord32<JSArrayBuffer::WasDetachedBit>(buffer_bit_field); |
| } |
| |
| void CodeStubAssembler::ThrowIfArrayBufferIsDetached( |
| SloppyTNode<Context> context, TNode<JSArrayBuffer> array_buffer, |
| const char* method_name) { |
| Label if_detached(this, Label::kDeferred), if_not_detached(this); |
| Branch(IsDetachedBuffer(array_buffer), &if_detached, &if_not_detached); |
| BIND(&if_detached); |
| ThrowTypeError(context, MessageTemplate::kDetachedOperation, method_name); |
| BIND(&if_not_detached); |
| } |
| |
| void CodeStubAssembler::ThrowIfArrayBufferViewBufferIsDetached( |
| SloppyTNode<Context> context, TNode<JSArrayBufferView> array_buffer_view, |
| const char* method_name) { |
| TNode<JSArrayBuffer> buffer = LoadJSArrayBufferViewBuffer(array_buffer_view); |
| ThrowIfArrayBufferIsDetached(context, buffer, method_name); |
| } |
| |
| TNode<Uint32T> CodeStubAssembler::LoadJSArrayBufferBitField( |
| TNode<JSArrayBuffer> array_buffer) { |
| return LoadObjectField<Uint32T>(array_buffer, JSArrayBuffer::kBitFieldOffset); |
| } |
| |
| TNode<RawPtrT> CodeStubAssembler::LoadJSArrayBufferBackingStore( |
| TNode<JSArrayBuffer> array_buffer) { |
| return LoadObjectField<RawPtrT>(array_buffer, |
| JSArrayBuffer::kBackingStoreOffset); |
| } |
| |
| TNode<JSArrayBuffer> CodeStubAssembler::LoadJSArrayBufferViewBuffer( |
| TNode<JSArrayBufferView> array_buffer_view) { |
| return LoadObjectField<JSArrayBuffer>(array_buffer_view, |
| JSArrayBufferView::kBufferOffset); |
| } |
| |
| TNode<UintPtrT> CodeStubAssembler::LoadJSArrayBufferViewByteLength( |
| TNode<JSArrayBufferView> array_buffer_view) { |
| return LoadObjectField<UintPtrT>(array_buffer_view, |
| JSArrayBufferView::kByteLengthOffset); |
| } |
| |
| TNode<UintPtrT> CodeStubAssembler::LoadJSArrayBufferViewByteOffset( |
| TNode<JSArrayBufferView> array_buffer_view) { |
| return LoadObjectField<UintPtrT>(array_buffer_view, |
| JSArrayBufferView::kByteOffsetOffset); |
| } |
| |
| TNode<Smi> CodeStubAssembler::LoadJSTypedArrayLength( |
| TNode<JSTypedArray> typed_array) { |
| return LoadObjectField<Smi>(typed_array, JSTypedArray::kLengthOffset); |
| } |
| |
| CodeStubArguments::CodeStubArguments( |
| CodeStubAssembler* assembler, Node* argc, Node* fp, |
| CodeStubAssembler::ParameterMode param_mode, ReceiverMode receiver_mode) |
| : assembler_(assembler), |
| argc_mode_(param_mode), |
| receiver_mode_(receiver_mode), |
| argc_(argc), |
| arguments_(), |
| fp_(fp != nullptr ? fp : assembler_->LoadFramePointer()) { |
| Node* offset = assembler_->ElementOffsetFromIndex( |
| argc_, SYSTEM_POINTER_ELEMENTS, param_mode, |
| (StandardFrameConstants::kFixedSlotCountAboveFp - 1) * |
| kSystemPointerSize); |
| arguments_ = |
| assembler_->UncheckedCast<WordT>(assembler_->IntPtrAdd(fp_, offset)); |
| } |
| |
| TNode<Object> CodeStubArguments::GetReceiver() const { |
| DCHECK_EQ(receiver_mode_, ReceiverMode::kHasReceiver); |
| return assembler_->UncheckedCast<Object>(assembler_->LoadFullTagged( |
| arguments_, assembler_->IntPtrConstant(kSystemPointerSize))); |
| } |
| |
| void CodeStubArguments::SetReceiver(TNode<Object> object) const { |
| DCHECK_EQ(receiver_mode_, ReceiverMode::kHasReceiver); |
| assembler_->StoreFullTaggedNoWriteBarrier( |
| arguments_, assembler_->IntPtrConstant(kSystemPointerSize), object); |
| } |
| |
| TNode<WordT> CodeStubArguments::AtIndexPtr( |
| Node* index, CodeStubAssembler::ParameterMode mode) const { |
| typedef compiler::Node Node; |
| Node* negated_index = assembler_->IntPtrOrSmiSub( |
| assembler_->IntPtrOrSmiConstant(0, mode), index, mode); |
| Node* offset = assembler_->ElementOffsetFromIndex( |
| negated_index, SYSTEM_POINTER_ELEMENTS, mode, 0); |
| return assembler_->IntPtrAdd(assembler_->UncheckedCast<IntPtrT>(arguments_), |
| offset); |
| } |
| |
| TNode<Object> CodeStubArguments::AtIndex( |
| Node* index, CodeStubAssembler::ParameterMode mode) const { |
| DCHECK_EQ(argc_mode_, mode); |
| CSA_ASSERT(assembler_, |
| assembler_->UintPtrOrSmiLessThan(index, GetLength(mode), mode)); |
| return assembler_->UncheckedCast<Object>( |
| assembler_->LoadFullTagged(AtIndexPtr(index, mode))); |
| } |
| |
| TNode<Object> CodeStubArguments::AtIndex(int index) const { |
| return AtIndex(assembler_->IntPtrConstant(index)); |
| } |
| |
| TNode<Object> CodeStubArguments::GetOptionalArgumentValue( |
| int index, TNode<Object> default_value) { |
| CodeStubAssembler::TVariable<Object> result(assembler_); |
| CodeStubAssembler::Label argument_missing(assembler_), |
| argument_done(assembler_, &result); |
| |
| assembler_->GotoIf(assembler_->UintPtrOrSmiGreaterThanOrEqual( |
| assembler_->IntPtrOrSmiConstant(index, argc_mode_), |
| argc_, argc_mode_), |
| &argument_missing); |
| result = AtIndex(index); |
| assembler_->Goto(&argument_done); |
| |
| assembler_->BIND(&argument_missing); |
| result = default_value; |
| assembler_->Goto(&argument_done); |
| |
| assembler_->BIND(&argument_done); |
| return result.value(); |
| } |
| |
| TNode<Object> CodeStubArguments::GetOptionalArgumentValue( |
| TNode<IntPtrT> index, TNode<Object> default_value) { |
| CodeStubAssembler::TVariable<Object> result(assembler_); |
| CodeStubAssembler::Label argument_missing(assembler_), |
| argument_done(assembler_, &result); |
| |
| assembler_->GotoIf( |
| assembler_->UintPtrOrSmiGreaterThanOrEqual( |
| assembler_->IntPtrToParameter(index, argc_mode_), argc_, argc_mode_), |
| &argument_missing); |
| result = AtIndex(index); |
| assembler_->Goto(&argument_done); |
| |
| assembler_->BIND(&argument_missing); |
| result = default_value; |
| assembler_->Goto(&argument_done); |
| |
| assembler_->BIND(&argument_done); |
| return result.value(); |
| } |
| |
| void CodeStubArguments::ForEach( |
| const CodeStubAssembler::VariableList& vars, |
| const CodeStubArguments::ForEachBodyFunction& body, Node* first, Node* last, |
| CodeStubAssembler::ParameterMode mode) { |
| assembler_->Comment("CodeStubArguments::ForEach"); |
| if (first == nullptr) { |
| first = assembler_->IntPtrOrSmiConstant(0, mode); |
| } |
| if (last == nullptr) { |
| DCHECK_EQ(mode, argc_mode_); |
| last = argc_; |
| } |
| Node* start = assembler_->IntPtrSub( |
| assembler_->UncheckedCast<IntPtrT>(arguments_), |
| assembler_->ElementOffsetFromIndex(first, SYSTEM_POINTER_ELEMENTS, mode)); |
| Node* end = assembler_->IntPtrSub( |
| assembler_->UncheckedCast<IntPtrT>(arguments_), |
| assembler_->ElementOffsetFromIndex(last, SYSTEM_POINTER_ELEMENTS, mode)); |
| assembler_->BuildFastLoop( |
| vars, start, end, |
| [this, &body](Node* current) { |
| Node* arg = assembler_->Load(MachineType::AnyTagged(), current); |
| body(arg); |
| }, |
| -kSystemPointerSize, CodeStubAssembler::INTPTR_PARAMETERS, |
| CodeStubAssembler::IndexAdvanceMode::kPost); |
| } |
| |
| void CodeStubArguments::PopAndReturn(Node* value) { |
| Node* pop_count; |
| if (receiver_mode_ == ReceiverMode::kHasReceiver) { |
| pop_count = assembler_->IntPtrOrSmiAdd( |
| argc_, assembler_->IntPtrOrSmiConstant(1, argc_mode_), argc_mode_); |
| } else { |
| pop_count = argc_; |
| } |
| |
| assembler_->PopAndReturn(assembler_->ParameterToIntPtr(pop_count, argc_mode_), |
| value); |
| } |
| |
| Node* CodeStubAssembler::IsFastElementsKind(Node* elements_kind) { |
| STATIC_ASSERT(FIRST_ELEMENTS_KIND == FIRST_FAST_ELEMENTS_KIND); |
| return Uint32LessThanOrEqual(elements_kind, |
| Int32Constant(LAST_FAST_ELEMENTS_KIND)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsDoubleElementsKind( |
| TNode<Int32T> elements_kind) { |
| STATIC_ASSERT(FIRST_ELEMENTS_KIND == FIRST_FAST_ELEMENTS_KIND); |
| STATIC_ASSERT((PACKED_DOUBLE_ELEMENTS & 1) == 0); |
| STATIC_ASSERT(PACKED_DOUBLE_ELEMENTS + 1 == HOLEY_DOUBLE_ELEMENTS); |
| return Word32Equal(Word32Shr(elements_kind, Int32Constant(1)), |
| Int32Constant(PACKED_DOUBLE_ELEMENTS / 2)); |
| } |
| |
| Node* CodeStubAssembler::IsFastSmiOrTaggedElementsKind(Node* elements_kind) { |
| STATIC_ASSERT(FIRST_ELEMENTS_KIND == FIRST_FAST_ELEMENTS_KIND); |
| STATIC_ASSERT(PACKED_DOUBLE_ELEMENTS > TERMINAL_FAST_ELEMENTS_KIND); |
| STATIC_ASSERT(HOLEY_DOUBLE_ELEMENTS > TERMINAL_FAST_ELEMENTS_KIND); |
| return Uint32LessThanOrEqual(elements_kind, |
| Int32Constant(TERMINAL_FAST_ELEMENTS_KIND)); |
| } |
| |
| Node* CodeStubAssembler::IsFastSmiElementsKind(Node* elements_kind) { |
| return Uint32LessThanOrEqual(elements_kind, |
| Int32Constant(HOLEY_SMI_ELEMENTS)); |
| } |
| |
| Node* CodeStubAssembler::IsHoleyFastElementsKind(Node* elements_kind) { |
| CSA_ASSERT(this, IsFastElementsKind(elements_kind)); |
| |
| STATIC_ASSERT(HOLEY_SMI_ELEMENTS == (PACKED_SMI_ELEMENTS | 1)); |
| STATIC_ASSERT(HOLEY_ELEMENTS == (PACKED_ELEMENTS | 1)); |
| STATIC_ASSERT(HOLEY_DOUBLE_ELEMENTS == (PACKED_DOUBLE_ELEMENTS | 1)); |
| return IsSetWord32(elements_kind, 1); |
| } |
| |
| Node* CodeStubAssembler::IsElementsKindGreaterThan( |
| Node* target_kind, ElementsKind reference_kind) { |
| return Int32GreaterThan(target_kind, Int32Constant(reference_kind)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsElementsKindLessThanOrEqual( |
| TNode<Int32T> target_kind, ElementsKind reference_kind) { |
| return Int32LessThanOrEqual(target_kind, Int32Constant(reference_kind)); |
| } |
| |
| Node* CodeStubAssembler::IsDebugActive() { |
| Node* is_debug_active = Load( |
| MachineType::Uint8(), |
| ExternalConstant(ExternalReference::debug_is_active_address(isolate()))); |
| return Word32NotEqual(is_debug_active, Int32Constant(0)); |
| } |
| |
| TNode<BoolT> CodeStubAssembler::IsRuntimeCallStatsEnabled() { |
| TNode<Word32T> flag_value = UncheckedCast<Word32T>(Load( |
| MachineType::Int32(), |
| ExternalConstant(ExternalReference::address_of_runtime_stats_flag()))); |
| return Word32NotEqual(flag_value, Int32Constant(0)); |
| } |
| |
| Node* CodeStubAssembler::IsPromiseHookEnabled() { |
| Node* const promise_hook = Load( |
| MachineType::Pointer(), |
| ExternalConstant(ExternalReference::promise_hook_address(isolate()))); |
| return WordNotEqual(promise_hook, IntPtrConstant(0)); |
| } |
| |
| Node* CodeStubAssembler::HasAsyncEventDelegate() { |
| Node* const async_event_delegate = |
| Load(MachineType::Pointer(), |
| ExternalConstant( |
| ExternalReference::async_event_delegate_address(isolate()))); |
| return WordNotEqual(async_event_delegate, IntPtrConstant(0)); |
| } |
| |
| Node* CodeStubAssembler::IsPromiseHookEnabledOrHasAsyncEventDelegate() { |
| Node* const promise_hook_or_async_event_delegate = |
| Load(MachineType::Uint8(), |
| ExternalConstant( |
| ExternalReference::promise_hook_or_async_event_delegate_address( |
| isolate()))); |
| return Word32NotEqual(promise_hook_or_async_event_delegate, Int32Constant(0)); |
| } |
| |
| Node* CodeStubAssembler:: |
| IsPromiseHookEnabledOrDebugIsActiveOrHasAsyncEventDelegate() { |
| Node* const promise_hook_or_debug_is_active_or_async_event_delegate = Load( |
| MachineType::Uint8(), |
| ExternalConstant( |
| ExternalReference:: |
| promise_hook_or_debug_is_active_or_async_event_delegate_address( |
| isolate()))); |
| return Word32NotEqual(promise_hook_or_debug_is_active_or_async_event_delegate, |
| Int32Constant(0)); |
| } |
| |
| TNode<Code> CodeStubAssembler::LoadBuiltin(TNode<Smi> builtin_id) { |
| CSA_ASSERT(this, SmiGreaterThanOrEqual(builtin_id, SmiConstant(0))); |
| CSA_ASSERT(this, |
| SmiLessThan(builtin_id, SmiConstant(Builtins::builtin_count))); |
| |
| int const kSmiShiftBits = kSmiShiftSize + kSmiTagSize; |
| int index_shift = kSystemPointerSizeLog2 - kSmiShiftBits; |
| TNode<WordT> table_index = |
| index_shift >= 0 ? WordShl(BitcastTaggedToWord(builtin_id), index_shift) |
| : WordSar(BitcastTaggedToWord(builtin_id), -index_shift); |
| |
| return CAST( |
| Load(MachineType::TaggedPointer(), |
| ExternalConstant(ExternalReference::builtins_address(isolate())), |
| table_index)); |
| } |
| |
| TNode<Code> CodeStubAssembler::GetSharedFunctionInfoCode( |
| SloppyTNode<SharedFunctionInfo> shared_info, Label* if_compile_lazy) { |
| TNode<Object> sfi_data = |
| LoadObjectField(shared_info, SharedFunctionInfo::kFunctionDataOffset); |
| |
| TVARIABLE(Code, sfi_code); |
| |
| Label done(this); |
| Label check_instance_type(this); |
| |
| // IsSmi: Is builtin |
| GotoIf(TaggedIsNotSmi(sfi_data), &check_instance_type); |
| if (if_compile_lazy) { |
| GotoIf(SmiEqual(CAST(sfi_data), SmiConstant(Builtins::kCompileLazy)), |
| if_compile_lazy); |
| } |
| sfi_code = LoadBuiltin(CAST(sfi_data)); |
| Goto(&done); |
| |
| // Switch on data's instance type. |
| BIND(&check_instance_type); |
| TNode<Int32T> data_type = LoadInstanceType(CAST(sfi_data)); |
| |
| int32_t case_values[] = {BYTECODE_ARRAY_TYPE, |
| WASM_EXPORTED_FUNCTION_DATA_TYPE, |
| ASM_WASM_DATA_TYPE, |
| UNCOMPILED_DATA_WITHOUT_PREPARSE_DATA_TYPE, |
| UNCOMPILED_DATA_WITH_PREPARSE_DATA_TYPE, |
| FUNCTION_TEMPLATE_INFO_TYPE}; |
| Label check_is_bytecode_array(this); |
| Label check_is_exported_function_data(this); |
| Label check_is_asm_wasm_data(this); |
| Label check_is_uncompiled_data_without_preparse_data(this); |
| Label check_is_uncompiled_data_with_preparse_data(this); |
| Label check_is_function_template_info(this); |
| Label check_is_interpreter_data(this); |
| Label* case_labels[] = {&check_is_bytecode_array, |
| &check_is_exported_function_data, |
| &check_is_asm_wasm_data, |
| &check_is_uncompiled_data_without_preparse_data, |
| &check_is_uncompiled_data_with_preparse_data, |
| &check_is_function_template_info}; |
| STATIC_ASSERT(arraysize(case_values) == arraysize(case_labels)); |
| Switch(data_type, &check_is_interpreter_data, case_values, case_labels, |
| arraysize(case_labels)); |
| |
| // IsBytecodeArray: Interpret bytecode |
| BIND(&check_is_bytecode_array); |
| sfi_code = HeapConstant(BUILTIN_CODE(isolate(), InterpreterEntryTrampoline)); |
| Goto(&done); |
| |
| // IsWasmExportedFunctionData: Use the wrapper code |
| BIND(&check_is_exported_function_data); |
| sfi_code = CAST(LoadObjectField( |
| CAST(sfi_data), WasmExportedFunctionData::kWrapperCodeOffset)); |
| Goto(&done); |
| |
| // IsAsmWasmData: Instantiate using AsmWasmData |
| BIND(&check_is_asm_wasm_data); |
| sfi_code = HeapConstant(BUILTIN_CODE(isolate(), InstantiateAsmJs)); |
| Goto(&done); |
| |
| // IsUncompiledDataWithPreparseData | IsUncompiledDataWithoutPreparseData: |
| // Compile lazy |
| BIND(&check_is_uncompiled_data_with_preparse_data); |
| Goto(&check_is_uncompiled_data_without_preparse_data); |
| BIND(&check_is_uncompiled_data_without_preparse_data); |
| sfi_code = HeapConstant(BUILTIN_CODE(isolate(), CompileLazy)); |
| Goto(if_compile_lazy ? if_compile_lazy : &done); |
| |
| // IsFunctionTemplateInfo: API call |
| BIND(&check_is_function_template_info); |
| sfi_code = HeapConstant(BUILTIN_CODE(isolate(), HandleApiCall)); |
| Goto(&done); |
| |
| // IsInterpreterData: Interpret bytecode |
| BIND(&check_is_interpreter_data); |
| // This is the default branch, so assert that we have the expected data type. |
| CSA_ASSERT(this, |
| Word32Equal(data_type, Int32Constant(INTERPRETER_DATA_TYPE))); |
| sfi_code = CAST(LoadObjectField( |
| CAST(sfi_data), InterpreterData::kInterpreterTrampolineOffset)); |
| Goto(&done); |
| |
| BIND(&done); |
| return sfi_code.value(); |
| } |
| |
| Node* CodeStubAssembler::AllocateFunctionWithMapAndContext(Node* map, |
| Node* shared_info, |
| Node* context) { |
| CSA_SLOW_ASSERT(this, IsMap(map)); |
| |
| Node* const code = GetSharedFunctionInfoCode(shared_info); |
| |
| // TODO(ishell): All the callers of this function pass map loaded from |
| // Context::STRICT_FUNCTION_WITHOUT_PROTOTYPE_MAP_INDEX. So we can remove |
| // map parameter. |
| CSA_ASSERT(this, Word32BinaryNot(IsConstructorMap(map))); |
| CSA_ASSERT(this, Word32BinaryNot(IsFunctionWithPrototypeSlotMap(map))); |
| Node* const fun = Allocate(JSFunction::kSizeWithoutPrototype); |
| STATIC_ASSERT(JSFunction::kSizeWithoutPrototype == 7 * kTaggedSize); |
| StoreMapNoWriteBarrier(fun, map); |
| StoreObjectFieldRoot(fun, JSObject::kPropertiesOrHashOffset, |
| RootIndex::kEmptyFixedArray); |
| StoreObjectFieldRoot(fun, JSObject::kElementsOffset, |
| RootIndex::kEmptyFixedArray); |
| StoreObjectFieldRoot(fun, JSFunction::kFeedbackCellOffset, |
| RootIndex::kManyClosuresCell); |
| StoreObjectFieldNoWriteBarrier(fun, JSFunction::kSharedFunctionInfoOffset, |
| shared_info); |
| StoreObjectFieldNoWriteBarrier(fun, JSFunction::kContextOffset, context); |
| StoreObjectFieldNoWriteBarrier(fun, JSFunction::kCodeOffset, code); |
| return fun; |
| } |
| |
| Node* CodeStubAssembler::MarkerIsFrameType(Node* marker_or_function, |
| StackFrame::Type frame_type) { |
| return WordEqual(marker_or_function, |
| IntPtrConstant(StackFrame::TypeToMarker(frame_type))); |
| } |
| |
| Node* CodeStubAssembler::MarkerIsNotFrameType(Node* marker_or_function, |
| StackFrame::Type frame_type) { |
| return WordNotEqual(marker_or_function, |
| IntPtrConstant(StackFrame::TypeToMarker(frame_type))); |
| } |
| |
| void CodeStubAssembler::CheckPrototypeEnumCache(Node* receiver, |
| Node* receiver_map, |
| Label* if_fast, |
| Label* if_slow) { |
| VARIABLE(var_object, MachineRepresentation::kTagged, receiver); |
| VARIABLE(var_object_map, MachineRepresentation::kTagged, receiver_map); |
| |
| Label loop(this, {&var_object, &var_object_map}), done_loop(this); |
| Goto(&loop); |
| BIND(&loop); |
| { |
| // Check that there are no elements on the current {object}. |
| Label if_no_elements(this); |
| Node* object = var_object.value(); |
| Node* object_map = var_object_map.value(); |
| |
| // The following relies on the elements only aliasing with JSProxy::target, |
| // which is a Javascript value and hence cannot be confused with an elements |
| // backing store. |
| STATIC_ASSERT(static_cast<int>(JSObject::kElementsOffset) == |
| static_cast<int>(JSProxy::kTargetOffset)); |
| Node* object_elements = LoadObjectField(object, JSObject::kElementsOffset); |
| GotoIf(IsEmptyFixedArray(object_elements), &if_no_elements); |
| GotoIf(IsEmptySlowElementDictionary(object_elements), &if_no_elements); |
| |
| // It might still be an empty JSArray. |
| GotoIfNot(IsJSArrayMap(object_map), if_slow); |
| Node* object_length = LoadJSArrayLength(object); |
| Branch(WordEqual(object_length, SmiConstant(0)), &if_no_elements, if_slow); |
| |
| // Continue with the {object}s prototype. |
| BIND(&if_no_elements); |
| object = LoadMapPrototype(object_map); |
| GotoIf(IsNull(object), if_fast); |
| |
| // For all {object}s but the {receiver}, check that the cache is empty. |
| var_object.Bind(object); |
| object_map = LoadMap(object); |
| var_object_map.Bind(object_map); |
| Node* object_enum_length = LoadMapEnumLength(object_map); |
| Branch(WordEqual(object_enum_length, IntPtrConstant(0)), &loop, if_slow); |
| } |
| } |
| |
| Node* CodeStubAssembler::CheckEnumCache(Node* receiver, Label* if_empty, |
| Label* if_runtime) { |
| Label if_fast(this), if_cache(this), if_no_cache(this, Label::kDeferred); |
| Node* receiver_map = LoadMap(receiver); |
| |
| // Check if the enum length field of the {receiver} is properly initialized, |
| // indicating that there is an enum cache. |
| Node* receiver_enum_length = LoadMapEnumLength(receiver_map); |
| Branch(WordEqual(receiver_enum_length, |
| IntPtrConstant(kInvalidEnumCacheSentinel)), |
| &if_no_cache, &if_cache); |
| |
| BIND(&if_no_cache); |
| { |
| // Avoid runtime-call for empty dictionary receivers. |
| GotoIfNot(IsDictionaryMap(receiver_map), if_runtime); |
| TNode<NameDictionary> properties = CAST(LoadSlowProperties(receiver)); |
| TNode<Smi> length = GetNumberOfElements(properties); |
| GotoIfNot(WordEqual(length, SmiConstant(0)), if_runtime); |
| // Check that there are no elements on the {receiver} and its prototype |
| // chain. Given that we do not create an EnumCache for dict-mode objects, |
| // directly jump to {if_empty} if there are no elements and no properties |
| // on the {receiver}. |
| CheckPrototypeEnumCache(receiver, receiver_map, if_empty, if_runtime); |
| } |
| |
| // Check that there are no elements on the fast {receiver} and its |
| // prototype chain. |
| BIND(&if_cache); |
| CheckPrototypeEnumCache(receiver, receiver_map, &if_fast, if_runtime); |
| |
| BIND(&if_fast); |
| return receiver_map; |
| } |
| |
| TNode<IntPtrT> CodeStubAssembler::GetArgumentsLength(CodeStubArguments* args) { |
| return args->GetLength(); |
| } |
| |
| TNode<Object> CodeStubAssembler::GetArgumentValue(CodeStubArguments* args, |
| TNode<IntPtrT> index) { |
| return args->GetOptionalArgumentValue(index); |
| } |
| |
| void CodeStubAssembler::Print(const char* s) { |
| std::string formatted(s); |
| formatted += "\n"; |
| CallRuntime(Runtime::kGlobalPrint, NoContextConstant(), |
| StringConstant(formatted.c_str())); |
| } |
| |
| void CodeStubAssembler::Print(const char* prefix, Node* tagged_value) { |
| if (prefix != nullptr) { |
| std::string formatted(prefix); |
| formatted += ": "; |
| Handle<String> string = isolate()->factory()->NewStringFromAsciiChecked( |
| formatted.c_str(), TENURED); |
| CallRuntime(Runtime::kGlobalPrint, NoContextConstant(), |
| HeapConstant(string)); |
| } |
| CallRuntime(Runtime::kDebugPrint, NoContextConstant(), tagged_value); |
| } |
| |
| void CodeStubAssembler::PerformStackCheck(TNode<Context> context) { |
| Label ok(this), stack_check_interrupt(this, Label::kDeferred); |
| |
| // The instruction sequence below is carefully crafted to hit our pattern |
| // matcher for stack checks within instruction selection. |
| // See StackCheckMatcher::Matched and JSGenericLowering::LowerJSStackCheck. |
| |
| TNode<UintPtrT> sp = UncheckedCast<UintPtrT>(LoadStackPointer()); |
| TNode<UintPtrT> stack_limit = UncheckedCast<UintPtrT>(Load( |
| MachineType::Pointer(), |
| ExternalConstant(ExternalReference::address_of_stack_limit(isolate())))); |
| TNode<BoolT> sp_within_limit = UintPtrLessThan(stack_limit, sp); |
| |
| Branch(sp_within_limit, &ok, &stack_check_interrupt); |
| |
| BIND(&stack_check_interrupt); |
| CallRuntime(Runtime::kStackGuard, context); |
| Goto(&ok); |
| |
| BIND(&ok); |
| } |
| |
| void CodeStubAssembler::InitializeFunctionContext(Node* native_context, |
| Node* context, int slots) { |
| DCHECK_GE(slots, Context::MIN_CONTEXT_SLOTS); |
| StoreMapNoWriteBarrier(context, RootIndex::kFunctionContextMap); |
| StoreObjectFieldNoWriteBarrier(context, FixedArray::kLengthOffset, |
| SmiConstant(slots)); |
| |
| Node* const empty_scope_info = |
| LoadContextElement(native_context, Context::SCOPE_INFO_INDEX); |
| StoreContextElementNoWriteBarrier(context, Context::SCOPE_INFO_INDEX, |
| empty_scope_info); |
| StoreContextElementNoWriteBarrier(context, Context::PREVIOUS_INDEX, |
| UndefinedConstant()); |
| StoreContextElementNoWriteBarrier(context, Context::EXTENSION_INDEX, |
| TheHoleConstant()); |
| StoreContextElementNoWriteBarrier(context, Context::NATIVE_CONTEXT_INDEX, |
| native_context); |
| } |
| |
| TNode<JSArray> CodeStubAssembler::ArrayCreate(TNode<Context> context, |
| TNode<Number> length) { |
| TVARIABLE(JSArray, array); |
| Label allocate_js_array(this); |
| |
| Label done(this), next(this), runtime(this, Label::kDeferred); |
| TNode<Smi> limit = SmiConstant(JSArray::kInitialMaxFastElementArray); |
| CSA_ASSERT_BRANCH(this, [=](Label* ok, Label* not_ok) { |
| BranchIfNumberRelationalComparison(Operation::kGreaterThanOrEqual, length, |
| SmiConstant(0), ok, not_ok); |
| }); |
| // This check also transitively covers the case where length is too big |
| // to be representable by a SMI and so is not usable with |
| // AllocateJSArray. |
| BranchIfNumberRelationalComparison(Operation::kGreaterThanOrEqual, length, |
| limit, &runtime, &next); |
| |
| BIND(&runtime); |
| { |
| TNode<Context> native_context = LoadNativeContext(context); |
| TNode<JSFunction> array_function = |
| CAST(LoadContextElement(native_context, Context::ARRAY_FUNCTION_INDEX)); |
| array = CAST(CallRuntime(Runtime::kNewArray, context, array_function, |
| length, array_function, UndefinedConstant())); |
| Goto(&done); |
| } |
| |
| BIND(&next); |
| CSA_ASSERT(this, TaggedIsSmi(length)); |
| |
| TNode<Map> array_map = CAST(LoadContextElement( |
| context, Context::JS_ARRAY_PACKED_SMI_ELEMENTS_MAP_INDEX)); |
| |
| // TODO(delphick): Consider using |
| // AllocateUninitializedJSArrayWithElements to avoid initializing an |
| // array and then writing over it. |
| array = |
| AllocateJSArray(PACKED_SMI_ELEMENTS, array_map, length, SmiConstant(0), |
| nullptr, ParameterMode::SMI_PARAMETERS); |
| Goto(&done); |
| |
| BIND(&done); |
| return array.value(); |
| } |
| |
| void CodeStubAssembler::SetPropertyLength(TNode<Context> context, |
| TNode<Object> array, |
| TNode<Number> length) { |
| Label fast(this), runtime(this), done(this); |
| // There's no need to set the length, if |
| // 1) the array is a fast JS array and |
| // 2) the new length is equal to the old length. |
| // as the set is not observable. Otherwise fall back to the run-time. |
| |
| // 1) Check that the array has fast elements. |
| // TODO(delphick): Consider changing this since it does an an unnecessary |
| // check for SMIs. |
| // TODO(delphick): Also we could hoist this to after the array construction |
| // and copy the args into array in the same way as the Array constructor. |
| BranchIfFastJSArray(array, context, &fast, &runtime); |
| |
| BIND(&fast); |
| { |
| TNode<JSArray> fast_array = CAST(array); |
| |
| TNode<Smi> length_smi = CAST(length); |
| TNode<Smi> old_length = LoadFastJSArrayLength(fast_array); |
| CSA_ASSERT(this, TaggedIsPositiveSmi(old_length)); |
| |
| // 2) If the created array's length matches the required length, then |
| // there's nothing else to do. Otherwise use the runtime to set the |
| // property as that will insert holes into excess elements or shrink |
| // the backing store as appropriate. |
| Branch(SmiNotEqual(length_smi, old_length), &runtime, &done); |
| } |
| |
| BIND(&runtime); |
| { |
| SetPropertyStrict(context, array, CodeStubAssembler::LengthStringConstant(), |
| length); |
| Goto(&done); |
| } |
| |
| BIND(&done); |
| } |
| |
| void CodeStubAssembler::GotoIfInitialPrototypePropertyModified( |
| TNode<Map> object_map, TNode<Map> initial_prototype_map, int descriptor, |
| RootIndex field_name_root_index, Label* if_modified) { |
| DescriptorIndexAndName index_name{descriptor, field_name_root_index}; |
| GotoIfInitialPrototypePropertiesModified( |
| object_map, initial_prototype_map, |
| Vector<DescriptorIndexAndName>(&index_name, 1), if_modified); |
| } |
| |
| void CodeStubAssembler::GotoIfInitialPrototypePropertiesModified( |
| TNode<Map> object_map, TNode<Map> initial_prototype_map, |
| Vector<DescriptorIndexAndName> properties, Label* if_modified) { |
| TNode<Map> prototype_map = LoadMap(LoadMapPrototype(object_map)); |
| GotoIfNot(WordEqual(prototype_map, initial_prototype_map), if_modified); |
| |
| if (FLAG_track_constant_fields) { |
| // With constant field tracking, we need to make sure that important |
| // properties in the prototype has not been tampered with. We do this by |
| // checking that their slots in the prototype's descriptor array are still |
| // marked as const. |
| TNode<DescriptorArray> descriptors = LoadMapDescriptors(prototype_map); |
| |
| TNode<Uint32T> combined_details; |
| for (int i = 0; i < properties.length(); i++) { |
| // Assert the descriptor index is in-bounds. |
| int descriptor = properties[i].descriptor_index; |
| CSA_ASSERT(this, Int32LessThan(Int32Constant(descriptor), |
| LoadNumberOfDescriptors(descriptors))); |
| // Assert that the name is correct. This essentially checks that |
| // the descriptor index corresponds to the insertion order in |
| // the bootstrapper. |
| CSA_ASSERT(this, |
| WordEqual(LoadKeyByDescriptorEntry(descriptors, descriptor), |
| LoadRoot(properties[i].name_root_index))); |
| |
| TNode<Uint32T> details = |
| DescriptorArrayGetDetails(descriptors, Uint32Constant(descriptor)); |
| if (i == 0) { |
| combined_details = details; |
| } else { |
| combined_details = Unsigned(Word32And(combined_details, details)); |
| } |
| } |
| |
| TNode<Uint32T> constness = |
| DecodeWord32<PropertyDetails::ConstnessField>(combined_details); |
| |
| GotoIfNot( |
| Word32Equal(constness, |
| Int32Constant(static_cast<int>(PropertyConstness::kConst))), |
| if_modified); |
| } |
| } |
| |
| TNode<String> CodeStubAssembler::TaggedToDirectString(TNode<Object> value, |
| Label* fail) { |
| ToDirectStringAssembler to_direct(state(), value); |
| to_direct.TryToDirect(fail); |
| to_direct.PointerToData(fail); |
| return CAST(value); |
| } |
| |
| } // namespace internal |
| } // namespace v8 |